Citations to this article
Abstract
Splanchnic metabolism was studied in the fed state during prolonged intravenous administration (30 g/h) of either fructose or glucose to hypertriglyceridemic men who had been maintained on a high-carbohydrate diet for 2 wk. Splanchnic exchange of amino acids and carbohydrates was quantified by measurement of splanchnic flow and of blood or plasma arteriohepatic venous concentration gradients. Results obtained in subjects receiving fructose were compared with those obtained in (a) similar subjects receiving glucose and (b) postabsorptive controls maintained on isocaloric, balanced diets. Mean arterial plasma levels of alanine, glycine, serine, threonine, methionine, proline, valine, leucine, histidine, lysine, and ornithine were significantly higher in subjects given fructose than in those give glucose (P less than 0.05). The mean arterial concentration and splanchnic uptake of alanine were significantly higher in subjects given fructose than in postabsorptive controls, despite a significantly lower fractional extraction of alanine in the former (P less than 0.05). The mean arterial plasma levels of serine and ornithine were significantly lower in subjects receiving fructose than in postabsorptive controls (P less than 0.05). About half of the administered fructose or glucose was taken up in the splanchnic region, where approximately 15% was converted to CO2 and 10% to lactate. Half of the fructose taken up in the splanchnic region was converted to glucose released from the liver. The amount of hexose carbon remaining for hepatic synthesis of liquids in subjects given fructose was less than half of that of subjects given glucose. These studies demonstrate that fructose and glucose have divergent effects on amino acid metabolism and that during hypercaloric infusion of glucose (as with fructose), the human liver is a major site of lactate production.
Authors
B M Wolfe, S P Ahuja, E B Marliss
Total citations by year
Citations to this article (30)
| Title and authors | Publication | Year |
|---|---|---|
|
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Tseng TS, Lin WT, Ting PS, Huang CK, Chen PH, Gonzalez GV, Lin HY |
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|
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Nutrition research (New York, N.Y.) | 2020 |
|
Triose Kinase Controls the Lipogenic Potential of Fructose and Dietary Tolerance
L Liu, T Li, Y Liao, Y Wang, Y Gao, H Hu, H Huang, F Wu, YG Chen, S Xu, S Fu |
Cell Metabolism | 2020 |
|
Fructose acutely stimulates NKCC2 activity in rat thick ascending limbs by increasing surface NKCC2 expression
GR Ares, KM Kassem, PA Ortiz |
American journal of physiology. Renal physiology | 2019 |
|
The extra-splanchnic fructose escape after ingestion of a fructose–glucose drink: An exploratory study in healthy humans using a dual fructose isotope method
C Francey, J Cros, R Rosset, C Crézé, V Rey, N Stefanoni, P Schneiter, L Tappy, K Seyssel |
Clinical Nutrition ESPEN | 2018 |
|
Fructose and NAFLD: The Multifaceted Aspects of Fructose Metabolism
P Jegatheesan, JP Bandt |
Nutrients | 2017 |
|
Specific regions of the brain are capable of fructose metabolism
SA Oppelt, W Zhang, DR Tolan |
Brain Research | 2017 |
|
Regular exercise prevents high-sucrose diet-induced fatty liver via improvement of hepatic lipid metabolism
W Aoi, Y Naito, LP Hang, K Uchiyama, S Akagiri, K Mizushima, T Yoshikawa |
Biochemical and Biophysical Research Communications | 2011 |
|
Soft drinks consumption and nonalcoholic fatty liver disease
W Nseir, F Nassar, N Assy |
World journal of gastroenterology : WJG | 2010 |
|
Severe Hypocalcemia Caused by Absorption of Sorbitol-Mannitol Solution during Hysteroscopy
GY Lee, JI Han, HJ Heo |
Journal of Korean Medical Science | 2009 |
|
Fructose consumption as a risk factor for non-alcoholic fatty liver disease
X Ouyang, P Cirillo, Y Sautin, S McCall, JL Bruchette, AM Diehl, RJ Johnson, MF Abdelmalek |
Journal of Hepatology | 2008 |
|
Hepatic adaptations to sucrose and fructose
ME Bizeau, MJ Pagliassotti |
Metabolism | 2005 |
|
Another feature of TURP syndrome: hyperglycaemia and lactic acidosis caused by massive absorption of sorbitol
CA Trépanier, MR Lessard, J Brochu, G Turcotte |
British Journal of Anaesthesia | 2001 |
|
Splanchnic and leg exchange of amino acids and ammonia in acute liver failure
JO Clemmesen, J Kondrup, P Ott |
Gastroenterology | 2000 |
|
Effects of Xylitol on Urea Synthesis in Normal Humans: Relation to Glucagon
O Hamberg, TP Almdal |
JPEN. Journal of parenteral and enteral nutrition | 1996 |
|
Lipid metabolism and substrate oxidation during intravenous fructose administration in cirrhosis
YT Kruszynska, DS Harry, LG Fryer, N McIntyre |
Metabolism | 1994 |
|
Hepatic metabolism during constant infusion of fructose; comparative studies with 31P-magnetic resonance spectroscopy in man and rats
S Masson, O Henriksen, A Stengaard, C Thomsen, B Quistorff |
Biochimica et Biophysica Acta (BBA) - General Subjects | 1994 |
|
Energy expenditure and substrate metabolism after oral fructose in patients with cirrhosis
YT Kruszynska, A Meyer-Alber, N Wollen, N McIntyre |
Journal of Hepatology | 1993 |
|
The contribution of naturally labelled 13C fructose to glucose appearance in humans
J Delarue, S Normand, C Pachiaudi, M Beylot, F Lamisse, JP Riou |
Diabetologia | 1993 |
|
Fructose metabolism in the human erythrocyte. Phosphorylation to fructose 3-phosphate
A Petersen, F Kappler, BS Szwergold, TR Brown |
Biochemical Journal | 1992 |
|
Forearm insulin- and non-insulin-mediated glucose uptake and muscle metabolism in man: Role of free fatty acids and blood glucose levels
PM Piatti, LD Monti, M Pacchioni, AE Pontiroli, G Pozza |
Metabolism | 1991 |
|
Splanchnic and renal exchange of infused fructose in insulin-deficient type 1 diabetic patients and healthy controls
O Björkman, R Gunnarsson, E Hagström, P Felig, J Wahren |
Journal of Clinical Investigation | 1989 |
|
Peripheral lactate and oxygen metabolism in man: The influence of oral glucose loading
RA Jackson, JB Hamling, BM Sim, MI Hawa, PM Blix, JD Nabarro |
Metabolism | 1987 |
|
An Evaluation of Biochemical Aspects of Intravenous Fructose, Sorbitol and Xylitol Administration in Man
L Sestoft |
Acta Anaesthesiologica Scandinavica | 1985 |
|
Effects of dietary substitution of mixed amino acids for glucose on the splanchnic metabolism of plasma triglycerides, cholesterol, carbohydrates, and amino acids in conscious fed baboons
BM Wolfe, RN Redinger, EB Marliss, DM Grace |
Metabolism | 1983 |
|
Current Topics in Cellular Regulation
G Cahill, T Aoki, R Smith |
Current Topics in Cellular Regulation | 1981 |
|
Mechanism of the hypolipemic effect of clofibrate in glucose-fed men
BM Wolfe, SP Ahuja, EB Marliss |
Metabolism | 1980 |
|
Fruktosetoleranz und -verwertung bei Gesunden und chronisch Leberkranken
D Oltmanns, J Adlung |
Zeitschrift für Ernährungswissenschaft | 1979 |
|
Initial splanchnic extraction of ingested glucose in normal man
J Radziuk, TJ McDonald, D Rubenstein, J Dupre |
Metabolism | 1978 |
|
Effects of intravenously administered fructose and glucose on splanchnic secretion of plasma triglycerides in hypertriglyceridemic men
BM Wolfe, SP Ahuja |
Metabolism | 1977 |
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