Differential tissue sensitivity to elevated endogenous insulin levels during experimental peritonitis in rats

Cecal Ligation and Puncture

Cecal ligation and puncture (CLP) is referred to as the "gold standard" rodent model for abdominal sepsis. CLP creates a continuously leaking, polymicrobial infectious focus in the abdomen. The abdominal cavity is opened under general anesthesia and analgesia and the cecum is exposed, ligated underneath the ileocecal valve, and punctured with a needle. A small amount of feces is pressed out through the puncture and the cecum is repositioned into the abdomen, which is then closed with single button sutures and tissue glue. CLP severity can be influenced via the length of the ligated cecum as well as the needle size. Within 24 h, animals develop clinical signs of a systemic bacterial infection. Analgesia, wide range antibiotic treatment, and fluid resuscitation should be administered during the acute phase of sepsis to increase the clinical relevance of the CLP model.

Experimental Abdominal Sepsis: Sticking to an Awkward but Still Useful Translational Model

Animal models are widely used to replicate human intra-abdominal infections. Different methodologies have been described and proposed in the scientific literature, including injection and surgical models. The aim of this review is to recapitulate the advantages and disadvantages of each method to help choose the most appropriate model for individual experimental purposes.

Investment of both essential fatty and amino acids to immunity varies depending on reproductive stage

Trade-offs among the key life-history traits of reproduction and immunity have been widely documented. However, the currency in use is not well-understood. We investigated how reproducing female side-blotched lizards, Uta stansburiana, allocate lipids versus proteins when given an immune challenge. We tested whether lizards would invest more in reproduction or immunity depending on reproductive stage. Females were given stable isotopes (¹⁵ N-leucine and ¹³ C-1-palmitic acid), maintained on a regular diet and given either a cutaneous biopsy or a sham biopsy (control). Stable isotopes were monitored and analyzed in feces and uric acid, skin biopsies, eggs, and toe clips. We found that lizards deposited both proteins and lipids into their healing wounds (immune-challenged), skin (control), and eggs (all) and that catabolism of proteins exceeded incorporation into tissue during wound-healing. Specifically, we found that healed biopsies of wounded animals had more leucine and palmitic acid than the nonregrown skin biopsies taken from unwounded control animals. Earlier in reproduction, lizards invested relatively more labeled proteins into healing their wound tissue, but not into unwounded skin of control animals. Thus, reproduction is sometimes favored over self-maintenance, but only in later reproductive stages. Finally, we documented positive relationships among the amount of palmitic acid deposited in the eggs, the amount of food eaten, and the amount of palmitic acid excreted, suggesting higher turnover rates of lipids in lizards investing highly in their eggs.

Protein sparing therapies in acute illness and obesity: a review of George Blackburn's contributions to nutrition science

Protein sparing therapies were developed to mitigate the harms associated with protein-calorie malnutrition and nitrogen losses induced by either acute illness or hypocaloric diets in patients with obesity. We review the development of protein sparing therapies in illness and obesity with a focus on the pioneering contributions of George Blackburn, MD, PhD. He recognized that protein-calorie malnutrition is a common and serious clinical condition and developed new approaches to its treatment in hospitalized patients. His work with stable isotopes and with animal models provided answers about the physiological nutritional requirements and metabolic changes across a spectrum of conditions with varying degrees of stress and catabolism. This led to improvements in enteral and parenteral nutrition for patients with acute illness. Blackburn also demonstrated that lean body mass can be preserved during weight loss with carefully designed very low calorie treatments which became known as the protein sparing modified fast (PSMF). We review the role of the PSMF as part of the comprehensive management of obesity.

Current understanding of sepsis: criticism and a proposal

The failure to improve outcome of septic patients may reflect flawed hypotheses pertaining to the pathogenesis of sepsis. Alternatively, it may represent the use of clinically irrelevant experimental animal models. To address these issues, an alternative hypothesis is proposed. It is suggested that leukocyte activation in sepsis is initiated by a priming effect of minuscule doses of endotoxin on leukocytes for enhanced responsiveness to minute doses of inflammatory mediators (or vice versa) as opposed to activation by overwhelming doses of endotoxin per se. The experimental impetus of this hypothesis has been provided by a novel rat model of sepsis precipitated by the co-administration of PAF and LPS at doses 1/1000 lower than those previously used to elicit sepsis in the same species.

The Sick and the Weak: Neuropathies/Myopathies in the Critically Ill

Critical illness polyneuropathies (CIP) and myopathies (CIM) are common complications of critical illness. Several weakness syndromes are summarized under the term intensive care unit-acquired weakness (ICUAW). We propose a classification of different ICUAW forms (CIM, CIP, sepsis-induced, steroid-denervation myopathy) and pathophysiological mechanisms from clinical and animal model data. Triggers include sepsis, mechanical ventilation, muscle unloading, steroid treatment, or denervation. Some ICUAW forms require stringent diagnostic features; CIM is marked by membrane hypoexcitability, severe atrophy, preferential myosin loss, ultrastructural alterations, and inadequate autophagy activation while myopathies in pure sepsis do not reproduce marked myosin loss. Reduced membrane excitability results from depolarization and ion channel dysfunction. Mitochondrial dysfunction contributes to energy-dependent processes. Ubiquitin proteasome and calpain activation trigger muscle proteolysis and atrophy while protein synthesis is impaired. Myosin loss is more pronounced than actin loss in CIM. Protein quality control is altered by inadequate autophagy. Ca(2+) dysregulation is present through altered Ca(2+) homeostasis. We highlight clinical hallmarks, trigger factors, and potential mechanisms from human studies and animal models that allow separation of risk factors that may trigger distinct mechanisms contributing to weakness. During critical illness, altered inflammatory (cytokines) and metabolic pathways deteriorate muscle function. ICUAW prevention/treatment is limited, e.g., tight glycemic control, delaying nutrition, and early mobilization. Future challenges include identification of primary/secondary events during the time course of critical illness, the interplay between membrane excitability, bioenergetic failure and differential proteolysis, and finding new therapeutic targets by help of tailored animal models.

Response to nutritional support and therapeutic approaches of amino acid and protein metabolism in surgical patients

The response to critical illness involves alterations in all aspects of metabolic control, favoring catabolism of body protein. In particular, body protein loss occurring as a result of the alteration of protein metabolism has been reported to be inversely correlated with the survival of critically ill patients. Despite the availability of various therapeutic modalities aiming to prevent loss of the body protein pool, such as total parenteral nutrition, enteral nutrition designed to provide excessive calories as a form of energy substrate, and protein itself, the loss of body protein cannot be prevented by any of these. Loss of the boyd protein store occurs as a consequence of the alteration of the intermediate metabolism that works for the production of energy substrate. This alteration of substrate metabolism may be linked to the alteration of protein metabolism. However, no specific factors regulating amino acid and protein metabolism have been identified. Thus, further investigations evaluating amino acid and protein metabolism are required to obtain better understanding of metabolic regulation in the body, which may lead to the development of novel and more effective therapeutic modalities for nutrition in the future.

Clinical and histological responses to laparoscopically-induced peritonitis in rats

PURPOSE: To evaluate the efficacy of inducing peritonitis in rats through laparoscopic cecal ligation (CL), by means of an elastic band. METHODS: Twelve Wistar rats were subjected to cecal ligated with an elastic band applied using a specially constructed applicator. In six of the animals (the CL group) the cecal sac was preserved intact whilst in the remaining animals (the CLP group) the sac was perforated with scissors. Clinical parameters, characteristics of the peritoneal cavity and cecum, and histological features of the cecal tissue were observed in all experimental animals 8 and 24 h after surgery. RESULTS: CLP animals exhibited at least one clinical sign of sepsis within the first 8 h of observation. The peritoneal liquid was observed to be clear in almost all members of the CLP. Polymorphonucleated cells were detected in the tunica serosa of the cecum of CLP animals. In contrast, all members of the CL group were alive after 24h, and of polymorphonucleated cells in the muscle layer of the cecal wall were observed. The presence of peritoneal liquid was not detected in CL animals. CONCLUSION: Although elastic ligation of the cecum was reproducible, puncture of the cecal sac was essential for induction of sepsis.

The significance of glucose, insulin and potassium for immunology and oncology: a new model of immunity

Background

A recent development in critical care medicine makes it urgent that research into the effect of hormones on immunity be pursued aggressively. Studies have demonstrated a large reduction in mortality as a result of infusion with glucose, insulin and potassium. Our work in the oncology setting has led us to propose that the principal reason for such an effect is that GIK stimulates lymphocytes to proliferate and attack pathogens, sparing the patient the stress of infection. That suggestion is based on a new model of immunity that describes the effect of hormones on lymphocytes. We hypothesized that the application of glucose, insulin, thyroid and potassium would awaken inert tumor infiltrating lymphocytes to destroy the tumor.

Methods

The antitumor effect of a thyroxine, glucose, insulin, and potassium (TGIK) combination was studied in a series of controlled experiments in murine models of tumor progression to assess the biologic activity of the formulation, the effect of route of administration, the effect on tumor type, and the requirement for insulin in the TGIK formulation.

Results

Melanoma and colon tumors inoculated with TGIK were significantly reduced in size or retarded in growth compared to controls injected with saline. I.P. and I.M. injections showed that the formulation had no effect systemically at the doses administered.

Conclusion

We conclude that TGIK has anti-tumor activity when administered intratumorally, probably by stimulating lymphocytes to attack tumors. This is similar to the effect of GIK on reducing sepsis in critical care patients. We suggest that when GIK is administered exogenously, it restores immune competence to the critically ill or cancer patient and causes destruction of pathogens or tumors, while endogenous resources are devoted to repair. This implies that hormonal therapy may be useful in treating various other pathologies involving immune suppression, as well as malignancies. We also propose research that could bring resolution of the controversy over mechanism and point the way to new therapeutic strategies for numerous diseases including chronic infections and auto-immune diseases.

Role of a hyaluronate-based membrane in the prevention of peritonitis-induced adhesions

Adhesions remain a significant postoperative complication of abdominal surgery; however, recent evidence suggests that physical barriers may reduce their incidence. Although these adhesion prevention barriers are efficacious when used under aseptic conditions, little is known about their use in the presence of peritonitis, which is associated with an increased incidence of abdominal adhesions. A sodium hyaluronate and carboxymethylcellulose bioresorbable membrane (HA membrane) has been shown recently to reduce postoperative adhesions in several animal models and in two clinical trials. To investigate the efficacy of HA membrane in the presence of peritonitis, generalized peritonitis was induced in rats by either cecal ligation and puncture (CLP) or cecal ligation (CL) alone. The ceca were resected after 12 hours, and animals were randomly assigned to receive or not receive HA membrane applied to the cecum. At day 7, abdominal adhesions and abscesses were scored. In the presence of peritonitis, HA membrane did not significantly reduce the number or tenacity of adhesions. A trend toward increased abscess formation was associated with HA membrane in the CL group. Although HA membrane has been shown to reduce the incidence and severity of abdominal adhesions under aseptic conditions, this study demonstrates that it is not efficacious in preventing abdominal adhesions in the presence of peritonitis. The association between HA membrane and abscess formation in the presence of experimental peritonitis requires further investigation.

Inter-organ protein and carbohydrate metabolic relationships during sepsis: necessary evils or uncanny coincidences?

Sepsis alters the dynamic flux of metabolic substrates between skeletal muscle and liver. Derangements in skeletal muscle glucose metabolism evoked by sepsis to a certain extent determine the rate of gluconeogenesis in the liver. In contrast, accelerated rates of gluconeogenesis do not drive net catabolism in skeletal muscle, nor does the upregulation of hepatic protein metabolism in sepsis or inflammation appear to be contingent or dependent upon the catabolism of muscle proteins during sepsis.

The stressful condition as a nutritionally dependent adaptive dichotomy

The injured body manifests a cascade of cytokine-induced metabolic events aimed at developing defense mechanisms and tissue repair. Rising concentrations of counterregulatory hormones work in concert with cytokines to generate overall insulin and insulin-like growth factor 1 (IGF-1), postreceptor resistance and energy requirements grounded on lipid dependency. Salient features are self-sustained hypercortisolemia persisting as long as cytokines are oversecreted and down-regulation of the hypothalamo-pituitary-thyroid axis stabilized at low basal levels. Inhibition of thyroxine 5'-deiodinating activity (5'-DA) accounts for the depressed T3 values associated with the sparing of both N and energy-consuming processes. Both the liver and damaged territories adapt to stressful signals along up-regulated pathways disconnected from the central and peripheral control systems. Cytokines stimulate liver 5'-DA and suppress the synthesis of transthyretin (TTR), causing the drop of retinol-binding protein (RBP) and the leakage of increased amounts of T4 and retinol in free form. TTR and RBP thus work as prohormonal reservoirs of precursor molecules which need to be converted into bioactive derivatives (T3 and retinoic acids) to reach transcriptional efficiency. The converting steps (5'-DA and cellular retinol-binding protein-I) are activated by T4 and retinol, themselves operating as limiting factors of positive feedback loops. Healthy adults with normal macrophage functioning and liver parenchymal integrity, who submitted to a stress of medium severity, are characterized by TTR-RBP plasma levels reduced by half and an estimated ten-fold increase in free ligand disposal to target cells during the days ensuing injury. This transient hyperthyroid and hyperretinoid climate creates a second defense line strengthening and fine-tuning the effects primarily initiated by cytokines. The suicidal behavior of thyroxine-binding globulin (TBG), corticosteroid-binding globulin (CBG), and IGFBP-3 allows the occurrence of peak endocrine and mitogenic influences at the site of inflammation. The production rate of TTR by the liver is the main determinant of both the hepatic release and blood transport of holoRBP, which explains why poor nutritional status concomitantly impairs thyroid- and retinoid-dependent acute-phase responses, hindering the stressed body to appropriately face the survival crisis. The prognostic significance of low TT4 blood levels may be assigned to the exhaustion of extrathyroidal hormonal pools normally stored in liver and plasma but markedly shrunken in protein-depleted states. These data offer new insights into the mechanisms whereby preexisting malnutrition and stressful complications are interrelated, emphasizing the pivotal role played by TTR in that context.

Gluconeogenesis and phosphoenergetics in rat liver during endotoxemia

BACKGROUND

During endotoxemia, glucose and energy metabolism varies depending on the stage, severity, and other conditions. In this study, gluconeogenesis from 13C-labeled alanine and phosphoenergetic state in rat liver during the acute phase of endotoxemia were concurrently observed by in vivo 13C and 31P NMR spectroscopy in a noninvasive manner.

MATERIALS AND METHODS

Lipopolysaccharide from Escherichia coli (10 mg/kg) was injected intravenously followed by infusion of [3-13C]alanine. In vivo 13C and 31P NMR spectra were alternately collected for 90 min with a 2.0 Tesla CSI Omega System.

RESULTS

In our experimental model, endotoxin increased the pulse rate without decreasing the blood pressure and elevated the blood sugar level, which suggests the so-called hyperdynamic state. Even under such conditions, a slight, but significant, impairment of the phosphoenergetic state in the liver (a decrease in ATP and an increase in Pi) was detected with 31P NMR spectroscopy. The 13C peaks of glucose C6 and Glu/Gln C2 of the liver in endotoxemia were significantly lower than those of the control, despite hyperglycemia in endotoxemia.

CONCLUSIONS

NMR spectroscopic studies suggest that the endotoxin caused the inhibition of gluconeogenic activity from the infused [3-13C]alanine and the TCA cycle accompanied by a deterioration in the phosphoenergetic state even in the hyperglycemic phase. Since the blood sugar level might be influenced by the systemic utilization of glucose, such direct measurements should prove important in the in vivo evaluation of glucose and energy metabolism in the liver.

Insulin stimulates lipoprotein lipase activity and synthesis in adipocytes from septic rats

Gram-negative sepsis suppresses lipoprotein lipase (LPL) activity in adipose tissue which contributes, in part, to the altered clearance of triglycerides. The suppression in LPL activity occurs when plasma insulin concentrations are elevated and insulin-stimulated glucose utilization is impaired. This study was planned to evaluate whether the presence of insulin resistance was responsible for the decrease in adipose LPL activity. Adipocytes were isolated from epididymal fat pads 24 h after inducing sepsis in male Lewis rats by intravenous injection of 4 x 10(8) colonies of live Escherichia coli/100 g body wt. The decrease in heparin-releasable (HR) LPL activity in adipocytes from the septic rats was evident at the time of isolation and maintained in a 20-h culture. After overnight incubation with insulin (10(-8) M), HR LPL activity was stimulated to a greater extent in adipocytes from septic rats (298%) than in adipocytes from control rats (88%). The insulin stimulation of LPL activity during sepsis could not be attributed to insulin-like growth factor-I (IGF-I) as adipocytes from septic rats appeared to be IGF-I resistant. Insulin-treatment (10(-8) M) increased LPL synthesis 99% in adipocytes from control rats and 136% in adipocytes from septic rats. Insulin treatment also led to a 65 and 62% increase in LPL mass in adipocytes from control and septic rats, respectively. These findings indicate that the sepsis-induced decrease in adipose LPL is not due to insulin resistance with respect to LPL. The insulin stimulation of LPL activity in adipocytes from septic rats appears to be mediated by an increase in LPL synthesis.

Peritonitis impairs intestinal absorption of proline and leucine in the rat

Systemic sepsis is associated with reduced mesenteric blood flow and impairment of metabolic and barrier functions of the small intestine. A study was performed in the rat to investigate the effect of sepsis induced by caecal ligation and double puncture on intestinal absorption of leucine and proline in vivo. Absorption was studied 24 h after caecal ligation and puncture by measuring intestinal disappearance and circulatory appearance of intraluminal 3H-labelled amino acid over a 60-min study period. Peritonitis resulted in a significant increase relative to controls in the mean (s.e.m.) percentage of leucine (67.2(3.6) versus 18.0(3.5), P < 0.001) and proline (64.7(6.0) versus 15.1(3.7), P < 0.001) remaining within the small intestine. There were significant decreases in portal venous and femoral arterial concentrations of leucine and proline in animals with sepsis. Intestinal amino acid absorption is impaired in this model.

Hepatobiliary complications in healthy, intra-abdominally infected, and high-output fistula rats receiving total parenteral nutrition

This study examines the pathophysiology of hepatobiliary complications induced by total parenteral nutrition (TPN) by using animal models that underwent cecal ligation to produce intra-abdominal infection and received an enterostomy to mimic a high-output fistula, which causes the interruption of enterohepatic circulation of bile salt. Aspartate transaminase was elevated after TPN (p < .05). Alkaline phosphatase was increased in animals receiving TPN plus an enterostomy (p < .05). Serum albumin was significantly decreased in animals receiving TPN plus undergoing cecal ligation or enterostomy (p < .05). Liver weight and liver protein and water content decreased in animals receiving TPN alone (p < .05). Liver water content increased in animals receiving TPN plus undergoing cecal ligation (p < .05). Liver lipid content increased after TPN and to a significant degree in rats receiving TPN plus undergoing cecal ligation or enterostomy (p < .05). Bile flow diminished after TPN and to a level reaching significance in animals receiving TPN plus undergoing cecal ligation or enterostomy (p < .05). Reduction of bile flow, decrease of biliary cholesterol secretion, and increase of biliary bilirubin secretion, which may be the cause of TPN-induced bilirubinate stones, were most significant in animals receiving TPN plus undergoing cecal ligation (p < .05). In conclusion, TPN can induce hepatic dysfunction and bilirubinate stones, but these complications are more common in animals with associated intra-abdominal infection or high-output fistula.

Alterations in levels of plasma phenylalanine and its catabolism in the liver of stressed rats

This study examined the relationship between elevation of blood phenylalanine (Phe) concentrations often observed in trauma or infected patients without hepatic dysfunction and alterations of liver Phe catabolism. Rats underwent pathophysiologically different stresses, either sepsis or scald injury. The catalytic activity of hepatic Phe hydroxylase (PH) in the septic rats, as measured after preincubation with Phe, decreased to 60% of the control values; this in vitro result suggests a reduction of enzyme species activated by its substrate. Phe was degraded in the septic rats to a similar extent to that in controls, when measured by pulse administration of [1-14C]-Phe. In the scalded rats whose plasma Phe level showed a comparable but transient increase, no significant alterations occurred in Phe catabolism and enzyme activities. The changes in plasma glucagon and catecholamine levels were consistent with those of the enzyme activities involved in Phe and tyrosine (Tyr) catabolism in the stressed groups. These results indicate that inadequate activation of native PH by regulatory mechanisms involving Phe in vivo was also associated with the accumulation of plasma Phe in infected rats during massive mobilization of amino acids from muscles under conditions of enhanced and sustained catabolism.

Metabolic effect of short-term total parenteral nutrition highly enriched with leucine or valine in rats recovering from severe trauma

The metabolic impact of infusing a large amount of leucine (Leu) or valine (Val) was examined with regard to the corrective effect of total parenteral nutrition (TPN). Rats recovering from severe sepsis received either Leu- or Val-enriched TPN solution for 30 hours. The in vivo behavior of the amino acids administered was explored by a pulse injection of 14C-labeled Leu or Val. The recovery of 14CO2 from Leu increased by 64% in the septic rats of Leu-TPN group (41% of dose; p less than .01), as compared with control rats receiving the same TPN solution, whereas no significant rise in the 14CO2 recovery from Val occurred in the septic rats given Val-TPN (45% of dose) in comparison with the corresponding controls. The enhancement of Leu catabolism to CO2 in the Leu-TPN group was compatible with the alterations of urinary nitrogen excretion, plasma Leu level, and metabolite contents of liver and muscle. The only difference in metabolite levels observed between the two TPN groups was in hepatic total adenine nucleotides. Plasma amino acid levels were largely unaffected by infusion of these TPN solutions highly enriched with branched-chain amino acids (45%), except for an approximately threefold elevation of the Val level in Val-TPN rats. Thus, when administered in a large quantity during such short-term TPN, Leu can exert its metabolic effect without causing an imbalance in plasma amino acids under severe catabolic conditions.

Glutamine metabolism in skeletal muscle of septic rats

The metabolism of skeletal muscle glutamine was studied in rats made septic by cecal ligation and puncture technique. Blood glucose was not significantly different in septic rats, but lactate, pyruvate, glutamine, and alanine were markedly increased. Conversely, blood ketone body concentrations were markedly decreased in septic rats. Both plasma insulin and glucagon were markedly elevated in septic rats. Sepsis increased the rates of glutamine production in muscle, but without marked effects on skin and adipose tissue preparations, with muscle production accounting for over 87% of total glutamine produced by the hindlimb. Sepsis produced decreases in the concentrations of skeletal muscle glutamine, glutamate, 2-oxoglutarate, and adenosine monophosphate (AMP). The concentrations of ammonia, pyruvate, and inosine monophosphate (IMP) were increased. Hindlimb blood flow showed no marked change in response to sepsis, but was accompanied by an enhanced net release of glutamine and alanine. The maximal activity of glutamine synthetase was increased only in quadriceps muscles of septic rats, whereas that of glutaminase was decreased in all muscles studied. Tyrosine release from incubated muscle preparation was markedly increased in septic rats; however, its rate of incorporation was markedly decreased. It is concluded that there is an enhanced rate of production of glutamine from skeletal muscle of septic rats. This may be due to changes in efflux and/or increased intracellular formation of glutamine; these suggestions are discussed.

The functional state of the beta cells in the pathogenesis of insulin-dependent diabetes mellitus

Besides the thymus-dependent immune system, growing evidence suggests that the functional state of the beta cell plays a role in the pathogenesis of Type 1 (insulin-dependent) diabetes. Increased incidence of diabetes has been described after increased insulin production and vice versa, and actual hyperinsulinemia has been observed in relation to the diabetogenesis. Prophylactic insulin treatment and intensive insulin therapy at diagnosis are discussed. The studies referred to are mostly animal model investigations of BB rats and NOD mice and-to a lesser degree- of streptozotocin- and encephalomyocarditis-virus-induced diabetes. Also human evidence exists, but naturally of a more sporadic character. Three possible mechanisms behind the beta cell sensitivity as a function of their activity are suggested: increased antigen expression (including both gangliosides and proteins) in beta cells with high activity which could activate the destruction caused by the immune system, and increased susceptibility to the toxicity of interleukins and to diabetogenic agents. With respect to developing preventive treatment the described research area may turn out to be very important. Further studies both in animal models and in humans are awaited.

Altered ketone body metabolism during gram-negative sepsis in the rat

To investigate why blood ketone bodies are depressed during sepsis, the production and utilization of ketone bodies was studied in fasted control, fasted, Escherichia coli-treated, fed control, and fed E coli-treated rats. Gram-negative sepsis was induced by intravenous (IV) injection of 8 x 10(7) live colonies of E coli per 100 g body weight. Food was removed from the fasted rats after E coli injection. Fed rats were infused intragastrically with a nutritionally adequate diet for 5 days before inducing sepsis. Twenty-four hours after E coli injection, blood ketone bodies were reduced in fasted septic rats and fed septic rats compared with their respective control rats. Ketogenesis and oxidation of labeled palmitate was not altered in hepatocytes from fasted E coli-treated rats. Yet, ketogenesis declined significantly in hepatocytes from fed E coli-treated rats. Oxidation of labeled palmitate was also significantly reduced in hepatocytes from fed E coli-treated rats. Utilization of ketone bodies as measured by the incorporation of [3-14C]beta-hydroxybutyrate into CO2, increased over threefold in the diaphragm, 12% in the heart, and 19% in the kidneys from the fasted E coli-treated rats. In the fed state, incorporation of [3-14C]beta-hydroxybutyrate into CO2 was elevated fivefold in the heart, fourfold in the diaphragm, and over threefold in the kidneys from the septic rats. These results suggest that in the fasted state, plasma ketone bodies remain low during gram-negative sepsis because peripheral tissues use more ketone bodies and because liver ketogenesis is not increased to compensate for the increased utilization. In the fed state, the reduction in blood ketone bodies appears to be attributed to both impaired ketogenic capacity and increased peripheral utilization.

Endotoxicosis modulates cytosolic free calcium and basal and ACTH-stimulated lipolysis in rat adipocytes

Lipolytic rates and intracellular Ca2+ concentration ([Ca2+]i) were determined under basal conditions and upon stimulation with adrenocorticotropic hormone (ACTH), norepinephrine (NE) and insulin (I), in adipocytes isolated from control and acutely endotoxin (ET)-treated rats (1 mg/100 g body weight, LD50 at 6 h). [Ca2+]i measurements were done using the fluorescent Ca2(+)-indicator Fura-2. NE and ACTH, but not I, produced a marked increase of [Ca2+]i in cells of both control and ET-treated rats. ET treatment elicited a significant increase in [Ca2+]i of resting cells, and enhanced the ACTH effect on this parameter. The changes in lipolytic activity correlated well with changes of [Ca2+]i induced by ACTH. The results indicate that ET-induced alterations in intracellular calcium homeostasis of adipocytes may contribute to the mediation of effects on fat mobilization during endotoxemia.

Fecal peritonitis: microbial adherence to serosal mesothelium and resistance to peritoneal lavage

Fecal contamination of the peritoneal cavity is a serious and potentially life-threatening event. While numerous models have been developed to study the pathogenesis of intraabdominal infection, to date, most investigations have failed to focus on the adherence of the contaminants to the serosal mesothelium. In the present investigation, the cecal ligation and puncture technique (CLP) was performed in Sprague-Dawley rats to study the following: (a) the kinetics of microbial adherence to the serosal mesothelium, (b) the stability of the aerobic and anaerobic intraperitoneal/mesothelial populations, following extended saline lavage, and (c) the impact of antimicrobial lavage on the stability of the mesothelial microbial populations. The Enterobacteriaceae rapidly colonized the serosal mesothelium and were the predominant flora up to 4 hours post-CLP. After 8 hours, the Bacteroides fragilis group represented the predominant peritoneal wash and mesothelial-associated microorganisms. Extended saline lavage failed to significantly reduce the mesothelial microbial populations. While antimicrobial lavage produced an immediate decrease in mesothelial microbial recovery, the results were transitory and the microbial populations achieved or exceeded prelavage levels at 24 hours postlavage. Microbial colonization of the peritoneal mesothelial surface is a rapid and stable phenomena following penetrating injury to the distal bowel. The results further suggest that the mesothelial populations are resistant to intraperitoneal lavage.

Administration of endotoxin, tumor necrosis factor, or interleukin 1 to rats activates skeletal muscle branched-chain alpha-keto acid dehydrogenase

Protein catabolic states (i.e., sepsis and trauma) are thought to be associated with accelerated oxidation of branched-chain amino acids (BCAA). Branched-chain alpha-keto acid dehydrogenase (BCKAD), the rate-limiting enzyme for BCAA oxidation by muscle, is regulated by phosphorylation/dephosphorylation. Skeletal muscle BCKAD was only 2-4% active in control rats. Intravenous injection of Salmonella enteritidis endotoxin (0.25-10 mg/kg) did not change total BCKAD activity, but increased the percent active enzyme in muscle three- to four-fold in 4-6 h. Identical results were observed in adrenalectomized rats pretreated with one dose of alpha-methylprednisolone (2.5 mg/kg i.p.) 30-60 min before saline or endotoxin injection, indicating that endotoxin's effect was not mediated by hypersecretion of adrenal hormones. Cortisone pretreatment of normal rats (100 mg/kg per d) for 2 d prevented endotoxin-induced activation of muscle BCKAD, suggesting that endogenous secretion products mediated BCKAD activation by endotoxin. Human recombinant tumor necrosis factor-alpha and/or IL-1 beta or alpha (50 micrograms/kg) increased muscle BCKAD activation two- to fourfold in normal rats 4-6 h after intravenous injection. We conclude that cytokine-mediated activation of muscle BCKAD may contribute to accelerated BCAA oxidation in septicemia.

Regulation of ketone body flux in septic patients

To assess the effect of sepsis on ketone body (KB) kinetics in humans, we measured in normal and septic subjects KB appearance rate (Ra) before (initial state) and during a rise of free fatty acids (FFA) level (intravenous infusion of a triglycerides emulsion). We studied normal subjects in postabsorptive state and septic patients when receiving an hypocaloric intravenous infusion of glucose and amino acids or 12 h after its interruption. When receiving glucose and amino acids infusion, septic patients had higher glucose and insulin levels than normal subjects, and despite lower FFA concentrations (255 +/- 44 vs. 480 +/- 51 mumol/l, P less than 0.05) comparable initial KB Ra (2.50 +/- 0.10 vs. 2.48 +/- 0.30 mumol.kg-1.min-1). Triglyceride infusion increased FFA to comparable values (septic 780 +/- 130, normal 730 +/- 45 mumol/l), but KB Ra rose in septic patients only to 3.7 +/- 1.1 instead of 7.7 +/- 1.1 mumol.kg-1.min-1 as in normal subjects (P less than 0.05). Somatostatin infusion decreased the hyperinsulinemia of septic patients but did not restore a normal ketogenesis. After interruption of nutriment infusion, septic patients had normal FFA levels and only mild hyperglycemia and hyperinsulinemia. Their initial KB Ra was not modified. However, their response of KB Ra (increase to 6.27 +/- 2.0 mumol.kg-1.min-1) to raised FFA levels (842 +/- 170 mumol/l) was comparable to the response of normal subjects. In conclusion, although septic patients receiving an hypocaloric parenteral nutrition had a depressed ketogenesis they were able to restore a normal ketogenic capacity after a short-time caloric deprivation. Glucose and/or insulin appears to have a major role in this modulation of hepatic ketogenesis.

Effect of administered human growth hormone on protein metabolism in septic rats

The effect of administered human growth hormone (hGH) on protein metabolism in septic rats was investigated. Fifty-three male Wistar rates with SVC cannulation were divided into four groups. Group I (n = 10) underwent sham-operation. Sepsis was induced by cecal ligation in group II (n = 19), group III (n = 10), and group IV (n = 14). Isocaloric, isonitrogenous glucose/amino acids were infused for 4 days. hGH was administered in group III (100 mU/day) and group IV (200 mU/day) every day. Cumulative nitrogen balance (mg/kg) in group IV was significantly higher than in group II (p less than 0.01): group I, 1264 +/- 355; group II, 117 +/- 693; group III, 92 +/- 735; group IV, 1001 +/- 279. Cumulative urinary excretion of 3-methylhistidine (3-MH, mg/kg) did not differ between group II and group IV: group I, 6.2 +/- 0.9; group II, 12.0 +/- 2.2; group III, 13.4 +/- 2.9; group IV, 10.5 +/- 2.3. Serum albumin level in group IV (1.8 +/- 0.2 g/dl) was significantly higher than in group II (1.5 +/- 0.2 g/dl) (p less than 0.01). Blood urea nitrogen level in group IV (12.6 +/- 2.3 mg/dl) was significantly lower than in group II (18.8 +/- 7.4 mg/dl) (p less than 0.05). Although serum levels of glucose, insulin, triglyceride, and phospholipid were higher in sepsis groups than in sham-operated group, those levels did not differ among sepsis groups. Administration of hGH, 200 mU/day, resulted in marked nitrogen retention and had little effect on 3-MH excretion.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of insulin and glucose oxidation in mediating the protein catabolism of burns and sepsis

We have investigated the responsiveness of protein kinetics to insulin and the role of glucose oxidation rate as a mediator of the protein catabolic response to burn injury and sepsis by assessing the response of leucine and urea kinetics to a 5-h hyperinsulinemic euglycemic clamp with and without the simultaneous administration of dichloroacetate (DCA) (to further increase glucose oxidation via stimulation of pyruvate dehydrogenase activity) in eight severely burned and eight septic patients. Leucine and urea kinetics were measured by the primed-constant infusions of [1(-13)C]leucine and [15N2]urea. Compared with controls, basal leucine kinetics (flux and oxidation) were significantly elevated (P less than 0.01) in both groups of patients. Hyperinsulinemia elicited significant (P less than 0.05) decreases in leucine kinetics in both groups of patients. Consistent with this observation, hyperinsulinemia caused urea production to decrease significantly (P less than 0.05) in both patient groups. The administration of DCA to patients during hyperinsulinemia elicited a significant increase in glucose oxidation rate compared with the clamp rate (P less than 0.05), and the percent of glucose uptake oxidized increased from 45.5 +/- 5.5 to 53.5 +/- 4.8%; yet the response of leucine and urea kinetics to the clamp plus DCA was not different from the response to the clamp alone. These results suggest that the maximal effectiveness of insulin to suppress protein breakdown is not impaired and that a deficit in glucose oxidation or energy supply is probably not playing a major role in mediating the protein catabolic response to severe burn injury and sepsis.

Interleukin-1 and the response to injury

Traumatic injury is the leading cause of morbidity and mortality in Americans less than 45 years old. People surviving the initial insult undergo metabolic, hemodynamic and immunologic changes which contribute to both early and late complications. Though necessary for normal immunologic response and for wound healing, pathologic alterations of IL-1 synthesis, degradation, and binding to receptors on both a local and systemic level could lead to these changes. Manipulation of IL-1-mediated effects might be of therapeutic utility in the management of trauma in the future.

Hyper and hypodynamic models of sepsis in guinea pigs

The acute metabolic response following experimentally induced sepsis can generally be classified as either hypodynamic ("low flow") or hyperdynamic ("high flow"). We have found that in conscious guinea pigs the bolus infusion of 10(10) live Escherichia coli bacteria can elicit either response, depending on the route of administration of the bacteria. Intravenous infusion results in the hypodynamic condition of septic shock in which oxygen consumption (VO2) is reduced to approximately 60% of the control level, plasma glucose is elevated 4 hr after infusion with a reversal to extreme hypoglycemia 12 hr after infusion, and body temperature is reduced by approximately 5 degrees C in 12 hr. In contrast, subcutaneous injection results in increased VO2, body temperature, and plasma glucose. In both models the concentration of cortisol, catecholamines and glucagon were elevated, but the responses were more pronounced in the hypodynamic model. In both cases, insulin concentration was decreased. These models of sepsis are useful because many aspects of response are comparable to man, they are simple to create, and they are consistent and reproducible.

Metabolic response to sepsis and trauma

This review examines current knowledge regarding the metabolic responses to trauma and sepsis. The factors which may mediate the responses are discussed and the potential value of pharmacological or nutritional manipulation is reviewed.

Skeletal muscle glutamine metabolism during sepsis in the rat

1. The effect of sepsis, induced by caecal ligation plus puncture (CLP) or endotoxin injection, on glutamine metabolism was studied in rat skeletal muscle. 2. The concentration of glutamine in muscle was decreased by CLP or after 24 or 48 hr after injection of endotoxin. However, the concentration was increased 3 hr after injection of endotoxin. 3. The plasma glutamine concentration was decreased by CLP, but it was unchanged after injection of endotoxin. 4. The rate of glutamine release from incubated stripped soleus muscles was increased in the muscles removed from animals subjected to CLP or from animals injected with endotoxin. 5. It is concluded that sepsis results in marked changes in skeletal muscle glutamine metabolism, which may be used as an early indicator of the septic state. During sepsis there is likely to be an increased demand for glutamine by the immune system, kidney and intestine. 6. This study provides evidence that during sepsis the rate of release of glutamine from the skeletal muscle per se is increased to a sufficient extent to satisfy this increased requirement.

Effect of total parenteral nutrition enriched in branched-chain amino acids on metabolite levels in septic rats

This study examined the effects of total parenteral nutrition (TPN) enriched with branched-chain amino acids (BCAAs) on metabolite levels of carbohydrate and protein metabolism in septic rats. Results also were obtained for standard amino acid hyperalimentation (conventional TPN). Septic peritonitis was induced in rats by cecal ligation and puncture. Two different experimental models were tested. In one, the two kinds of TPN were administered to the operated rats during the progress of sepsis (the septic phase). In the other, TPN was started immediately after surgical removal of the focal cecum (the recovery phase). The conventional and BCAA-enriched TPN solutions were isocaloric and isonitrogenous except that the percentage of BCAAs in the total amino acids by weight was 35.8% in BCAA-enriched TPN and 20.9% in conventional TPN. On the fifth postoperative day, TPN was discontinued, the animals were killed, and samples of arterial blood, liver, and rectus abdominis muscle were taken. BCAA-enriched TPN had a significant effect on nitrogen balance and survival rate in the septic phase model, and on muscle adenine nucleotide content in both models. Other metabolites showed similar changes in the two TPN groups. These results indicate that BCAA supplement in TPN improves nitrogen balance and peripheral cellular energy status and is thus clinically beneficial in preventive therapy for increased catabolism.

Down-regulation of insulin receptors in Propionibacterium acnes-activated macrophages in the mouse

Intraperitoneal administration of Propionibacterium acnes in CD-1 mice was associated with the reduction in number of insulin receptors in peritoneal macrophages (M phi), and with elevated levels of insulin in plasma and the peritoneal cavity. When insulin levels returned to normal, insulin receptors in P. acnes-M phi were still reduced. Insulin appears to contribute significantly to the down-regulation of the M phi-insulin receptors during the early stage of activation. Other biologically active substances released during M phi activation might assume greater influence on insulin resistance in activated M phi at a later stage. The induction of transient hyperinsulinemia in P. acnes-treated mice might be attributed to the effect of concurrently elevated interleukin-1 (IL-1) released in the early course of M phi activation.

Nutritional considerations for the burned patient

The metabolic response to injury is one of marked catabolic hormonal predominance resulting in hypermetabolism and protein wasting. Energy expenditure increases with increasing severity of injury, but reaches a maximum of twice resting energy expenditure when 50 per cent TBSA is burned. We agree with the nutritional recommendations of the group at the Boston Shriner's Burn Institute and the Massachusetts General Hospital. These include providing calories at twice the resting energy expenditure, as predicted by the Harris-Benedict equations, for patients with greater than 30 per cent BSAB; protein is provided at 2.5 gm per kg per day based on ideal body weight. It is important to recognize that these are optimal goals, but their attainment must be governed by safety considerations for the patient. It is probably safe to supplement intake with a multivitamin and vitamin C, as well as zinc, but our understanding of micronutrient therapy for stressed patients is rudimentary.

Alterations in metabolite levels in carbohydrate and energy metabolism of rat in hemorrhagic shock and sepsis

For comparison of the extent of metabolite content alteration caused by etiologically different types of shock, septic peritonitis and hemorrhagic shock (mean arterial blood pressure at 40 mm Hg for 1 h or 2 h) were produced in rats. Contents of metabolites were determined in the liver and the muscle. Characteristic differences were found in the alteration modes of hepatic lactate level, muscle adenine nucleotide concentrations, and muscle protein content between these shock models. Rapid and significant alterations were observed in the levels of adenine nucleotides, glucose-6-phosphate and lactate in the liver in both types of shock. Hepatic energy charge and contents of glycogen and protein also significantly decreased. On the other hand, noticeable changes in the muscles were elevation of lactate level and the decrease of phosphocreatine and protein concentrations. Another distinct change was the decrease of total adenine nucleotide content in the muscle of septic rats, whereas it remained unchanged in the muscle of hemorrhagic shock rats. Thus, the changes of metabolite levels did not occur simultaneously in different tissues, and their rate and magnitude varied between different types of shock. The difference in adaptive response of metabolism may result in pathophysiologic diversity in shock.

Regulation of glucose metabolism by altered pyruvate dehydrogenase activity. I. Potential site of insulin resistance in sepsis

Regulation of the pyruvate dehydrogenase (PDH) complex has been demonstrated to be a key mechanism in the control of carbohydrate oxidation and conservation of glucose carbon. The effect of sterile inflammation and chronic sepsis (small and large abscess) on the activity of the PDH complex was examined in liver and skeletal muscle. Sepsis altered the proportion of PDH in the active, dephosphorylated form. In hepatic tissue, sterile inflammation leads to a 2.5-fold increase in the proportion of active PDH complex compared to fed control. The same increase in the proportion of active PDH complex was observed in rats with a small septic abscess. However, when the severity of septic episode was increased, the proportion of active PDH complex decreased relative to sterile inflammation or small septic abscess animals. A different pattern in the response to sterile inflammation and sepsis on the proportion of active PDH complex was observed in skeletal muscle compared to liver. In contrast to liver, sterile inflammation did not alter the proportion of active PDH in skeletal muscle. In addition, sepsis (either small or large septic abscess) resulted in a 3-fold decrease in the proportion of active PDH relative to fed control or sterile inflammatory animals. The decrease in the proportion of active PDH complex in sepsis was associated with a corresponding increase in the skeletal muscle acetyl-CoA/CoA ratio. The mechanism responsible for lowered PDH complex activity may have been due to increased PDH kinase activity, secondary to increased skeletal muscle acetyl-CoA/CoA ratios.

The effects of endotoxaemia on protein metabolism in skeletal muscle and liver of fed and fasted rats

The response of muscle and liver protein metabolism to either a single or three successive daily injections of an endotoxin (Escherichia coli lipopolysaccharide, serotype 0127 B8; 1 mg/ml, 0.3 mg/100 g body wt.) was studied in vivo in the fed rat, and at 24 and 30 h after endotoxin treatment during fasting. In the fed rats there was a catabolic response in muscle, owing to a 60-100% increase in muscle protein degradation rate, and a 52% fall in the synthesis rate. Although there was a 20% decrease in food intake, the decrease in protein synthesis was to some extent independent of this, since rats treated with endotoxin and fasted also showed a lower rate of muscle protein synthesis, which was in excess of the decrease caused by fasting alone. The mechanism of this decreased protein synthesis involved decreased translational activity, since in both fed and fasted rats there was a decreased rate of synthesis per unit of RNA. This occurred despite the fact that insulin concentrations were either maintained or increased, in the fasted rats, to those observed in fed rats. In the liver total protein mass was increased in the fed rats by 16% at 24 h, and the fractional synthesis rate at that time was increased by 35%. In rats fasted after endotoxin treatment the liver protein mass was not decreased as it was in the control fasted rats, and the fractional synthesis rate was increased by 22%. In both cases the increased synthesis rate reflected an elevated hepatic RNA concentration. The extent of this increase in hepatic protein synthesis was sufficient at one point to compensate for the fall in estimated muscle protein synthesis, so that the sum total in the two tissues was maintained.

Diminished pressor response to exogenous norepinephrine and angiotensin II in septic, unanesthetized rats: evidence for a prostaglandin-mediated effect

Despite elevated plasma concentrations of norepinephrine (NE), septic patients generally have normal or low mean arterial pressure (MAP) and systemic vascular resistance. We tested the hypothesis that sustained sepsis in rats results in relative hyporesponsiveness to the pressor actions of NE and angiotensin II (AII). Sprague-Dawley rats were studied 48 hr after sepsis was induced by cecal ligation. Sham-operated rats served as controls. Carotid artery and jugular venous catheters were placed under halothane anesthesia and the rats were allowed to waken fully in restraining cages. Peak increments in MAP were measured after bolus iv doses of NE (0.125-8.0 micrograms/kg) or AII (0.0125-0.5 microgram/kg). Some rats were pretreated with indomethacin (5 mg/kg, iv) 30 min prior to the dose-response study. Data were fitted to a two-parameter hyperbolic function and the resulting curves were compared by analysis of variance. Compared with controls, sepsis decreased the pressor response to both NE (P less than 0.0001) and AII (P less than 0.0001). Indomethacin restored responsiveness toward normal for both pressor agents (P less than 0.0001). It is concluded that sepsis is associated with hyporesponsiveness to two chemically dissimilar vasopressors and that this phenomenon may be mediated by prostaglandins.

The effect of major thermal injury on plasma ketone body levels

Eleven patients with more than 30% total body surface burns were studied during 3 days of starvation and three more days of unrestricted feeding following their injury. All patients developed marked protein mobilization as demonstrated by 3rd day urine nitrogen excretion of 17.1 g daily compared to control excretion of 11.8 g N daily. As a group, the patients failed to mount the expected ketonemic response during their initial period of starvation. Whereas normal fasted controls achieved plasma ketone body levels of 727 +/- 81 mumol/liter, the burn patients responded with an average level of 385 +/- 77 mumol/liter (p less than 0.01).

The effect of major thermal injury and carbohydrate-free intake on serum triglycerides, insulin, and 3-methylhistidine excretion

The severely burned patient responds differently to starvation ketosis in the early stage of injury as compared to the normal individual. A similar response has been observed in the patient after skeletal trauma and sepsis. In order to determine the extent of muscle protein contribution and the mechanism(s) involved, 11 burn patients with 35% to 80% BSA burn were resuscitated using carbohydrate-free solutions for 3 days followed by unrestricted intake. Blood was drawn daily and 24-hour urinary nitrogens were determined. Controls consisted of 10 preoperative elective surgical patients and two normal volunteers. The burned patients lost a mean +/- SEM of 17.1 +/- 1.72 g nitrogen per day on the third day. The mean +/- SEM ketone body response on the third day for burned patients was 385 +/- 77 mumol/l compared to 727 +/- 81 mumol/l for control patients. The mean +/- SEM 3-methylhistidine loss for burned patients on the third day was 9.83 +/- 0.82 mumol/kg compared to 3.6 mol/kg for control patients. Insulin levels on the third day of fast were three times the normal group. This insulin increase may be the modulating factor that suppresses excessive fat mobilization. This metabolic response causes a lower plasma ketone level, which may then necessitate the need for continued protein catabolism for glucose production for certain tissues. The protein contribution to the hypercatabolic response as assessed by increased urinary nitrogen losses is in part supported by an increased muscle protein breakdown as indicated by increased 3-methylhistidine excretion.

Metabolism of amino acids, protein and glucose in fat pads of traumatized rats

Soft tissue injury to one hindlimb of rats was used to test the response to trauma of metabolism in epididymal fat pads. Degradation of [1-14)C]leucine was lower on day 2 after injury, but not on days 1 or 3, whether or not glucose or insulin were provided. Although trauma did not affect the basal rate of release of 14CO2, lactate or pyruvate from fat pads incubated with [U-14C] glucose, the stimulation by insulin of these processes was smaller in fat pads of 2 day traumatized than of normal animals. These results suggest that trauma due to injury may decrease the capacity for utilization of leucine and glucose by adipose tissue. Release of alanine, glutamine and glutamate by fat pads incubated with leucine was also lower on day 2. This decreased efflux could not be accounted for by changes in net protein breakdown or in pyruvate availability and probably reflected their reduced de novo synthesis due to the diminished release of nitrogen from leucine.

Effects of glucocorticoids on glutamine metabolism in skeletal muscle

The effects of dexamethasone on nitrogen and amino acid metabolism in the dog were studied in order to gain insight into the role of glucocorticoids in accelerated proteolysis and altered metabolism of glutamine in catabolic illnesses. After dexamethasone administration at a dose of 0.44 mg X day-1 X kg-1, nitrogen balance shifted from slightly positive (+0.126 g N X day-1 X kg-1) to markedly negative (-0.278 g N X day-1 X kg-1). This was associated with a 23% fall in total free amino acid nitrogen in skeletal muscle, with 80% of the decline accounted for by a decrease in glutamine. Plasma glutamine concentration decreased by 26%, although total plasma free amino acid nitrogen was unchanged because of a 49% increase in alanine. The alterations in intracellular and circulating levels of glutamine were not accompanied by measurable changes in glutamine synthetase or glutaminase activities in skeletal muscle. Hindquarter amino acid flux measurements demonstrated that the decline in intracellular glutamine concentration was associated with a marked increase in glutamine efflux from skeletal muscle. This occurred in spite of minimal changes in the intracellular/extracellular glutamine gradient. It is concluded that accelerated muscle glutamine release caused by glucocorticoids is a major contributor to the decreased glutamine levels in muscle that occur during critical illnesses.

Infusion of branched chain-enriched amino acid solutions in sepsis

The goal of nutritional support in sepsis is, as in other conditions, to prevent the use of endogenous protein as an energy substrate and, ideally, to promote the synthesis of proteins specifically required in responding to the particular insult or stress at hand. This entails provision of an utilizable fuel, in sufficient quantity, that does not inhibit the use of endogenous nonprotein sources; preservation of the existing protein mass by minimizing skeletal muscle and visceral proteolysis; provision of amino acids in sufficient quantity and in the appropriate proportions such that protein synthesis is optimized. Specifically, this includes the synthesis of those proteins required to maintain hyperdynamic function of the essential organs as well as the hepatic and leukocytic synthesis of proteins required in immunologic defense. This study has assessed one aspect of this goal during the administration of nutrient solutions differing primarily in branched chain amino acid content. We conclude that leucine is fundamental among the branched chain amino acids for reducing skeletal muscle proteolysis. Solutions designed for sepsis or stress should, therefore, contain adequate amounts of this amino acid.

Metabolism of protein, amino acids, and glucose and their response to insulin in atria and cardiac myocytes of traumatized rats

Soft tissue injury to one hindlimb of rats was used to test the metabolic response of atrial and ventricular muscle to trauma. Effects of insulin on muscle metabolism were also studied. In myocytes and atria from normal animals, insulin increased protein synthesis and decreased protein degradation. For myocytes of rats at one and two days after trauma, this effect of insulin on proteolysis could not be detected. Over the next two days, the inhibitory effect returned to normal. Insulin also did not increase protein synthesis on day 1, but did thereafter. In atria, in contrast to heart cells, the inhibitory effect of insulin on proteolysis was enhanced at two and three days after trauma, and its stimulation of protein synthesis was unaltered. Insulin increased carbohydrate metabolism in both myocytes and atria of normal rats and traumatized rats after 2 days, and trauma did not alter this response. In myocytes, but not atria, trauma led to a faster oxidation of leucine and a significant rise in the production of alanine. Production of glutamine and glutamate was not affected in either tissue. These results show that the metabolic responses to trauma of atrial and ventricular muscle differ considerably.