Rate of elimination of the intralipid fat emulsion from the circulation in ICU patients

Soybean oil: a potentially new intravascular perfusate

BACKGROUND

Given that micelles of lipids are colloids, the hypothesis was generated that the rapid administration of large volumes of soybean oil micelles would be an effective perfusion fluid. We also hypothesized that oxygen loading would be enhanced due to the greater solubility of oxygen in lipids compared to water.

METHODS

A 100% lethal mouse model of blood loss was used to compare the ability of soybean oil micelles to that of Ringer's lactate, blood and other fluids, with respect to raising and maintaining the blood pressure for one hour. Oxygen on- and off-loading of various concentrations of soybean oil micelles was determined using mass spectroscopy. Nitric oxide uptake by micelles was also determined in a similar fashion.

RESULTS

A 20% soybean oil emulsion was superior to Ringer's lactate in raising and maintaining blood pressure. A 20% soybean oil emulsion with 5% albumin added was superior to shed blood as well as solutions comprised of 5% albumin added to either normal saline or Ringer's lactate. There was a linear relationship between oxygen content and micelle concentration between 10% and 30%. Off-loading of oxygen from the micelles was nearly as fast as off-loading from water. Nitric oxide also loaded preferentially onto soybean oil micelles.

CONCLUSIONS

(1) Soybean oil emulsions were superior to other fluids in restoring and maintaining the blood pressure; (2) oxygen-carrying ability of soybean oil micelles exceeds that of water and follows Henry's law between 10% and 30% w/v oil content; (3) nitric oxide was carried by the micelles; (4) animals receiving soybean oil micelles did not exhibit fat embolization; (5) colloids comprised of soybean oil-containing micelles may be used to replace blood loss and may be used to deliver oxygen and other potentially therapeutic gases such as nitric oxide to tissues.

Metabolic pattern and lipid oxidation during abdominal surgery: midazolam versus propofol

Propofol is formulated in an emulsion similar to 10% Intralipid, and several authors have suggested that fat accumulates during its infusion. In this study we used indirect calorimetry to measure lipid metabolism during abdominal surgery in patients anesthetized with propofol, using midazolam as a control. Thirty patients were randomly divided into three groups: Group P (propofol 2 mg/kg + 5 mg.kg-1.h-1, n = 13); Group M (midazolam, n = 9), and Group I (midazolam + 10% Intralipid at rates similar to those infused in Group P, n = 8). They were monitored with an indirect calorimeter for 90 min. Data including oxygen consumption (VO2), CO2 production (VCO2), energy expenditure (EE), respiratory quotient (RQ), and lipid utilization were obtained every 15 min. VO2 increased in all groups at 45 min in respect to basal measurements with no differences between them. VCO2 decreased significantly only in Groups P and I, although no differences between the three groups were observed. EE did not vary in any of the groups. RQ decreased in all groups at 30 min, being significantly higher in Group M than in Groups P and I. Lipid oxidation increased in all groups from the beginning of the study reaching a plateau at 45 min. The lipid oxidation was higher in Groups P and I than in Group M, and coincided (80-100 g/24 h) with the amount of fat administered exogenously (85.4 g/ 24 h for a patient of 70 kg). Compared to VO2, VCO2, and EE, propofol behaves as other anesthetics. The fat administered in its formulation is metabolized in a preferential way, although it is likely that larger doses than those studied in our patients partially accumulate.

Pharmacologic influence on nutrition support therapy: use of propofol in a patient receiving combined enteral and parenteral nutrition support

Propofol is a lipid-based sedative that provides 1.1 kcal/mL. Because propofol has rapid onset and quick recovery, it is becoming used widely in critical care units. A 15-year-old critically ill pregnant patient received specialized nutrition support concomitantly with propofol infusion for sedation. A serum triglyceride concentration obtained on day 6 of the propofol infusion was 1100 mg/dL with no previous history of hyperlipidemia. Caloric intakes from propofol averaged 1275 kcal/d (range 445 to 2354 kcal/d) over a 5-day period. Infusion of propofol or any other lipid-based drug must be monitored closely when given in conjunction with enteral or parenteral nutrition to avoid the pitfalls of overfeeding and hypertriglyceridemia. Enteral and parenteral formulas must be manipulated to provide optimal nutrient intakes while not overfeeding with fat when using increased amounts of lipid-based drugs.

Survival to lipopolysaccharide, cytokine release and phagocyte functions in mice treated with different total parenteral nutrition regimens

Effects on host defenses of Total Parenteral Nutrition (TPN) with long- (LCT) and medium-chain triglycerides (MCT) were studied. Survival to lipopolysaccharide (LPS) challenge, blood clearance of Escherichia coli, in vivo and in vitro production of tumor necrosis factor-alpha (TNF-alpha) and interleukin-6 (IL-6) were investigated. In BALB/c mice, LCTs produced a 25% reduction in mortality, compared with controls. TPN performed with a LCT plus MCT mixture reduced mortality by 50%. Spasms appeared after 18 h and 12 h respectively in mice treated with LCT-MCT mixture or LCTs alone, respect to controls (8 h). The LCT-MCT mixture produced a 67% blood clearance of E. coli after 1 h, while the treatment with LCTs alone had no significant effects compared to controls (about 40%). The LCT-MCT mixture induced a 50% increase in chemiluminescence respect to controls. A 33% increase was observed in rats treated with LCTs alone. TNF-alpha serum levels after challenge with LPS were not modified by any of the triglycerides or their combinations. IL-6 increased by 43% with LCT-MCT mixture and by 39% with LCTs alone versus controls. After a 3 h in vitro treatment with LCTs, human monocytes were stimulated to release TNF-alpha at levels higher than those stimulated with the LCT-MCT mixture, and respect to controls. In contrast after 3 h the stimulation with LCT-MCT mixture induced a higher IL-6 release than controls and cells stimulated with LCTs alone, or with LPS.

Nutrition care of patients with acute and chronic respiratory failure

Nutrition is intimately linked to pulmonary function and an understanding of these relationships have therapeutic utility. Malnutrition is known to be associated with impaired mechanical function of the lung in both chronic and acute respiratory insufficiency. Refeeding results in improvement in functional characteristics and may be critical in the weaning of patients from mechanical ventilation. In contrast, overfeeding may result in an increased ventilatory demand resulting in the inability to wean from respiratory support. This article considers the background as well as recommendations for the nutritional care of patients with acute and chronic respiratory failure.

Use of even-numbered carbon atom dicarboxylic salts in parenteral nutrition as fuel substrate

Sebacic acid (C10), a saturated, straight-chain dicarboxylic acid with 10 carbon atoms in disodic salt form, was given intravenously to two groups of healthy male volunteers in order to evaluate its possible use in total parenteral nutrition. The first group, composed of six subjects, received 1000 mg of sebacate as a bolus; six other subjects (second group) received 10 g of sebacate dissolved in 500 mL of double-distilled water at an infusion rate of 3.33 g/h over 3 hours. The serum sebacate data for each subject were analyzed by computer, using biexponential fit corresponding to a 2-compartment open model. The distribution half-life (t1/2) was 0.34 +/- 0.06 hour and the elimination phase was rather rapid (Ke = 2.10 +/- 0.38/h); the volume of the central compartment was 2.79 +/- 0.54 L and the volume of tissue compartment 3.72 +/- 0.14 L. These data showed a good tissue fixation of sebacate. The plasma clearance was evaluated to be 5.96 +/- 2.19 L/h and the renal clearance was 19.22 +/- 10.69 L/h, indicating that a tubular secretion of C10 takes place. The serum concentration of sebacate raised to the maximal value at the end of the infusion (180 minutes), corresponded to 480.50 +/- 43.02 micrograms/mL. Respiratory and metabolic parameters were evaluated by indirect calorimetry from the beginning of the infusion for 210 minutes. The O2 consumption (VO2 mL/min per square meter) remained essentially unchanged throughout the experiment (from 154.3 +/- 28.3 at 0 to 155.3 +/- 39.5 at time 180 minutes).(ABSTRACT TRUNCATED AT 250 WORDS)

Overview of biochemical markers used for nutrition support

Altered metabolism has been shown to exist in the settings of surgical stress, cancer, cirrhosis, sepsis, and trauma. Each condition is characterized by varying degrees of alteration in metabolic processes, and within a given patient, these metabolic alterations will change as the patient's status changes. Nutrition support is an integral part of the metabolic management of critically ill patients. Metabolic changes impact nutritional substrate requirements and utilization. As the patient's clinical condition deteriorates, clinical signs and symptoms become less reliable in predicting or assessing the existing physiologic state. Objective measurements are needed to define the metabolic status during these physiologic changes. The purpose of this article is to review selected indices that have been used to identify abnormalities in nutritional substrate metabolism. Although some of these tests are readily available and inexpensive, many have not been used outside of the research setting and, therefore, their clinical utility has yet to be determined. However, their use as research tools for defining metabolism warrants their inclusion in order to assist the clinician in interpreting research studies. The biochemical markers discussed include glucose, lactate, pyruvate, triglycerides, beta-hydroxybutyrate, acetoacetate, urinary nitrogen, acute phase proteins, visceral proteins, 3-methylhistidine, plasma amino acids, oxygen consumption, and resting energy expenditure. Each marker is defined in terms of its biochemical significance, and the literature describing changes that occur in various stress states is cited.

[Energy substrates in parenteral nutrition]

The most appropriate nutriment for total parenteral feeding (TPF) must be nutritionally efficient, safe and easy to use. Glucose is the most used carbohydrate as it has most of these qualities, as well as a high rate of metabolism by all tissues. It has not been clearly demonstrated that the administration of exogenous insulin with glucose improves nitrogen retention. Substitutes for glucose, such as fructose, maltose, galactose or polyols (xylitol, surbitol, glycerol) are not really superior to glucose itself. On the other hand, they have major side-effects. Therefore, they are not much used as energy substrates for TPF, at least not for long term TPF. Intravenous fat emulsions have taken an important place as a source of energy during TPF. Fat emulsions containing long chain triglycerides (LCT) supply essential fatty acids (EFA) (linolenic and linoleic acids), thus preventing EFA deficiency. The metabolism of fat emulsions is influenced by various factors: age, metabolic and nutritional status, the amount of glucose intake, insulin deficiency, sepsis, heparin therapy. Recently, medium chain triglycerides (MCT) have been proposed as an alternative energy source. The latter are cleared more rapidly from the blood, and are therefore less liable to be deposited in the liver and adipose tissue; they are also oxidized more quickly and more completely. MCT are safe to use at a rate of less than 0.12 g.kg-1.h-1 and with a MCT/LCT ratio less than 3 to 1. The simultaneous administration of glucose prevents an acceleration of ketogenesis. MCT/LCT emulsions are a safe and effective source of calories. It is important that those patients for whom such nutriment may be of particular interest should be identified. Fat emulsions associated with glucose seem to be more efficient in terms of nitrogen sparing effect than glucose alone. They also avoid the problems due to the infusion of large amounts of glucose (excessive carbon dioxide production, fatty infiltration of the liver), while there is no EFA deficiency. If the infusion of TPF nutriment must be continuous in intensive care patients, or during the postoperative period, cyclic nocturnal parenteral nutrition over a 12 or 16 hour period may be used in patients who are not in a catabolic state, or only mildly so. This is a safe and efficient method of nutritional support, which reduces the incidence rate of TPF-induced cholestasis.

Inhibition of immunoglobulin synthesis in vitro by intravenous lipid emulsion (Intralipid)

Intravenous lipid emulsions depress lymphocyte proliferative responses and granulocyte function at concentrations found in the blood circulation during their administration. The effects of Intralipid, a widely used intravenous lipid emulsion, were measured on immunoglobulin production in vitro by pokeweed mitogen-activated lymphocytes as a test of B-cell function. Intralipid decreased IgG, IgM, and IgA production at soybean oil triglyceride concentrations of 2.5-20 mg/ml occurring in the blood circulation during Intralipid infusion. The effects on IgM and IgA production were highest and that on IgG production lowest. Hydrocortisone-sensitive and concanavalin A-inducible suppressor cells were more sensitive to Intralipid than other cell populations. In vivo Ig production may not be equally disturbed, inasmuch as Intralipid concentrations in the lymph nodes and the spleen may be lower than in the blood circulation. However, care should be taken to prevent Intralipid concentrations from becoming high enough to depress immune responses.

Hemodynamic and vascular permeability effects of lipid emulsion in the isolated canine lung lobe

The isolated canine right lower lung lobe (RLL) perfused with autogenous blood at constant flow was used to study the effects of a parenteral lipid emulsion, Liposyn 10%, on pulmonary hemodynamics and vascular permeability. Lobes were placed into four groups: (1) control lobes (C; n = 6), which were infused via the lobar artery with normal saline at 1 ml.min-1 for 30 min; (2) lipid emulsion lobes (L; n = 6), which were infused via the lobar artery with Liposyn 10% at 1 ml.min-1 for 15 min; (3) lobes infused with both Liposyn 10% and 0.25 to 6.0 mg of lipoprotein lipase (LL; n = 4); and (4) lobes infused with 0.13 to 6.0 mg of lipoprotein lipase alone (LP; n = 6). Liposyn infusion alone caused no changes in lobar hemodynamics compared to group C. Over time there were no differences between groups C and L on venous PO2, PCO2, or pH. Post-infusion weight gain (over 10 to 14 min) averaged 0.23 +/- 0.08, 0.19 +/- 0.07, 0.66 +/- 0.23, and 3.00 +/- 1.46 g.min-1.100 g-1 RLL for groups C, L, LP, and LL, respectively (p less than 0.05, for group LL compared to Group C). The pulmonary filtration coefficient (Kf) was determined as an index of vascular permeability. Groups C and L had Kf values of 0.07 +/- 0.01 and 0.28 +/- 0.22 ml.min-1.mm Hg-1.100 g-1 (mean +/- SE), respectively, which did not differ significantly (p greater than 0.05). Liposyn 10%, given in a concentration larger than that used clinically, produced no untoward pulmonary vascular effects.(ABSTRACT TRUNCATED AT 250 WORDS)

Gram-positive bacterial sepsis in rat and tissue lipolytic activity on commercial parenteral fat emulsions

To study the influence of a gram-positive sepsis on the metabolism of circulating lipids, fasted rats were injected with saline (control group) or with a suspension of heat-killed or live Staphylococcus aureus. 18 h later, body temperature was increased, while albuminemia and ketonemia were decreased in the group injected with heat-killed bacteria, as opposed to the control group. Passing from these groups to the group injected with live bacteria, more differences appeared: increase of triglyceridemia and free cholesterolemia; decrease of esterified cholesterol levels and especially of the in vitro activity of diaphragm, heart and adipose tissue lipoprotein lipase and of hepatic lipase. The decrease of lipolytic activities occurred whether they were measured on a fat emulsion containing long-chain or medium- and long-chain triglycerides. The fact that for the latter the activity was always higher than for the former suggests that the host infected with gram-positive bacteria would clear exogenous fat more easily in the case of medium-chain triglycerides.

Clinical and experimental effects of medium-chain-triglyceride-based fat Emulsions—A review

Although total parenteral nutrition usually includes lipids, traditional long-chain triglyceride (LCT) emulsions do not fulfil the energy-providing role allotted to them. The special properties of medium-chain triglycerides (MCTs) and fatty acids led to replacement of part of the infused LCTs by MCTs. The present review shows that: 1. MCT/LCT emulsions are as safe and as well tolerated as the traditional emulsions, and contain enough essential fatty acids to meet patients' needs. 2. Relative to LCT emulsions, MCT/LCT emulsions exhibit a number of differences: * More rapid clearance from the circulation. Lipoprotein lipase and hepatic lipase hydrolyse them preferentially. * Decreased liability to be deposited as fat, in adipose tissue and liver. They do not overload the reticula-endothelial system, which may better preserve its capacity to phagocytose bacteria. * More rapid and complete oxidation, Faster energy provision for all tissues, even though a small part is dissipated in a clinical non-relevant thermogenesis and by o-oxidation. They are ketogenic if infused alone. * Concomitant administration of glucose does not influence their clearance rate, only slightly decreases their oxidation rate, but prevents the acceleration of ketogenesis. Two other properties of MCT/LCT emulsions are probable, though not confirmed: * exchanges of lipids between artificial fat particles and plasma lipoproteins may be less with these emulsions than with LCTs, though it is not yet known what effect diminished disturbance of lipoprotein homeostasis has on the organism. * The nitrogen-sparing effect of a TPN regimen containing MCTs/LCTs seems better than a regimen providing LCTs only.

Intralipid removal from plasma of uraemic and intensive care patients

The removal rates from plasma of Intralipid and (125)I-albumin, simultaneously injected i.v., were analyzed in 10 chronic renal failure (CRF) patients. The results were compared with 9 intensive care unit (ICU) patients and five healthy subjects as controls. The fractional removal rates of Intralipid (k2) were significantly lower for the CRF patients compared to both ICU patients and healthy subjects. The initial plasma concentration of Intralipid, calculated by extrapolation of the elimination curve back to zero-time (y0), showed significantly higher values for CRF patients and healthy subjects compared to ICU patients. Removal curves expressed as ratios between Intralipid and (125)I-albumin paralleled the elimination curves for Intralipid, which suggests that the slope of the curves depends on Intralipid removal and not on leakage of macromolecules from the circulation. The very low initial plasma concentration of Intralipid in the ICU patients cannot be explained by a hyperdynamic circulation, but may be attributed to a rapid first passage disappearance of Intralipid from plasma into tissues such as the pulmonary vasculature.

Medium-chain triglyceride-based fat emulsions: an alternative energy supply in stress and sepsis

Medium-chain triglycerides (MCTs) and medium-chain fatty acids (MCFAs) have special physicochemical properties such as small molecular weight, small interfacial tension against water, and for the fatty acids, solubility in biological fluids. As a result the metabolic pathways followed by these fats in an organism are different and simpler, or identical but more rapid, than those followed by long-chain triglycerides (LCTs) and long-chain fatty acids (LCFAs). Consequently the MCTs have found numerous applications in oral or enteral nutrition and, more recently, in parenteral nutrition. The infusion of conventional fat emulsions in stress and sepsis is still controversial. A main question is whether an MCT supply can be beneficial for these patients. In this review, we will discuss different aspects of modified lipid and protein metabolism: exchanges between exogenous fat particles and lipoproteins; exogenous fat clearance, storage, and oxidation; reticuloendothelial system function; nitrogen balance; and hepatic function. For each of these perturbations, the MCT/LCT and structured lipid emulsions are theoretically capable to provide an appropriate solution. The efficiency of these emulsions has been demonstrated experimentally on animal models of stress and sepsis. However, the value of MCT-based fat emulsions for these pathological states has still to be ascertained by clinical studies.

The metabolic and nutritional effects of injury and sepsis

The existence of a co-ordinated response to stress of a variety of causes has clearly been established. Basically, this consists of an elevation in energy expenditure and an increased breakdown of skeletal muscle protein. In addition, glucose level in the plasma increases as a result of increased synthesis and decreased uptake of glucose into cells. Release of fatty acid into the plasma is also increased, and an elevation in the proportion of energy derived from oxidation of fatty acids is observed. This response is qualitatively very different from that seen in simple starvation, where a progressive reduction in energy expenditure and a reduction in the synthesis of glucose allows fat to become the major energy-producing substrate and also allows sparing of body protein stores. The mechanisms responsible for this altered pattern of metabolism are probably primarily hormonal in nature, with adrenaline, cortisol and glucagon being the major catabolic stimulants. Some evidence exists, however, for alteration in intracellular pathway metabolism. Within the past decade a new class of mediators of the stress response, the cytokines, has been recognized. These substances are protein products of circulating monocytes and the way in which they integrate into the control of the stress response has not been completely elucidated. At present there is evidence that they can stimulate production of catabolic hormones, and also they may well have direct effects in enhancing protein catabolism in muscle. At present the main method for modification of the stress response remains the provision of energy and amino acid, either intravenously or enterally. In the present state of our knowledge, 30-40 kcal kg-1 day-1 would appear to be adequate for most patients, with half provided as fat. Amino acids 3 g kg-1 day-1 will provide adequate nitrogen. It must be said, however, that the most effective method of modifying the stress response is removal of the source of stress by surgery, antibiotics or other primary therapy.

Plasma clearance of fat emulsion during continuous heparin infusion

Intravenous fat tolerance was tested in two groups of patients given a continuous i.v. infusion of heparin for several days. One group of 11 patients with deep vein thrombosis (DVT) of the leg was given 25,000-35,000 IU heparin daily for 4-5 days. The other group comprised 10 patients who had central venous catheters (CVC) for total parenteral nutrition. These patients were given 20,000 IU heparin daily for 6 days as prophylaxis against CVC-related thrombosis. In the DVT group heparinization was associated with a 44% decrease in plasma fat removal capacity (P less than 0.05). This reduction persisted for 2 days after the discontinuation of heparin therapy. In the CVC group the plasma fat removal capacity decreased by 29% during heparinization (P greater than 0.05, NS). During heparinization activated partial thromboplastin time was more than three times the basal value in the DVT group but less than twice those in the CVC group. One week after the heparin therapy the serum triglyceride levels were higher in both groups compared with initial values (DVT group: 1.2 +/- 0.2 s.e. mean vs. 1.7 +/- 0.3 mmol/l; P less than 0.05. CVC group: 1.0 +/- 0.1 vs. 1.4 +/- 0.2 mmol/l; NS). The possibility that full-dose heparinization reduces plasma fat removal capacity and that this may be due to a partial depletion of lipoprotein lipase stores is discussed.

The Henry M. Vars Award. The effect of lipid emulsions on reticuloendothelial system function in the injured animal

Use of intravenous lipid emulsions in trauma and sepsis still remains controversial. In order to examine the impact lipid emulsions have on host defense against bacterial infection during total parenteral nutrition (TPN), 56 male Sprague-Dawley rats underwent jugular cannulation and were randomly divided into three groups, each receiving one of three TPN regimens. All regimens delivered approximately 250 kcal/kg X body weight/day, of which 12.5 g were as amino acids. Group 1 received 100% of the nonprotein calories as glucose (AA + G). Group 2 was given 50% of the nonprotein calories as a longchain triglyceride emulsion (100% LCT). Group 3 received 50% of nonprotein calories as a mixed lipid system, composed of medium- and long-chain triglycerides (75% MCT/25% LCT). After 24 hr on intravenous nutrition, all animals received bilateral septic femur fractures and were continued on TPN for 3 days. On the last day, the level of bacteremia and the in vivo response to an intravenous challenge of 59Fe-labeled Escherichia coli were examined. Three days following the septic injury, animals given MCT as part of their lipid calories were not bacteremic, whereas the other groups had greater than 10(2) cfu/ml of blood. Animals receiving TPN with MCT sequestered a greater percentage of exogenously administered bacteria in the liver and sequestered less in the lung compared to animals given 100% LCT (p less than 0.05). From these data, we conclude that parenteral nutrition formulas where LCT has been partially replaced with MCT may better support host bactericidal capacity than similar regimens comprised of LCT as the sole lipid source.