Albumin and fibrinogen syntheses increase while muscle protein synthesis decreases in head-injured patients

Odile Mansoor1,3, Marc Cayol2, Pierre Gachon3, Yves Boirie3, Pierre Schoeffler1, Christiane Obled2, and Bernard Beaufrère3

1 Département de Réanimation, Centre Hospitalier Universitaire, 63003 Clermont Ferrand; 2 Unité d'Etude du Métabolisme Azoté, Institut National de la Recherche Agronomique de Theix, 63122 St. Genès-Champandle; and 3 Laboratoire de Nutrition Humaine, Université d'Auvergne Centre de Recherche en Nutrition Humaine, 63009 Clermont-Ferrand, France

    ABSTRACT
Top
Abstract
Introduction
Materials
Results
Discussion
References

The effect of trauma on protein metabolism was investigated in the whole body, muscle, and liver in severely head-injured patients presenting an acute inflammatory response by comparison to fed control subjects receiving a similar diet. Nonoxidative leucine disposal (an index of whole body protein synthesis) and muscle, albumin, and fibrinogen synthesis were determined by means of a primed, continuous infusion of L-[1-13C]leucine. Nonoxidative leucine disposal increased by 28% in the patients (P < 0.02). Fractional muscle protein synthesis rate decreased by 50% (P < 0.01) after injury. Fractional and absolute fribrinogen synthesis rates were multiplied by two and nine, respectively, after injury (P < 0.001). Albumin levels were lower in patients (25.2 ± 1.2 g/l, means ± SE) than in controls (33.7 ± 1.2 g/l, P < 0.001). However, fractional albumin synthesis rates were increased by 60% in patients (11.4 ± 1.0%/day) compared with controls (7.3 ± 0.4%/day, P < 0.01). Therefore, 1) head trauma induces opposite and large changes of protein synthesis in muscle and acute-phase hepatic proteins, probably mediated by cytokines, glucocorticoids, and other stress hormones, and 2) in these patients, hypoalbuminemia is not due to a depressed albumin synthesis.

inflammation; cytokines; leucine; tracers

    INTRODUCTION
Top
Abstract
Introduction
Materials
Results
Discussion
References

DURING THE CLASSIC "flow phase" after trauma, critically ill patients exhibit an important loss of body proteins due to an imbalance between proteolysis, which increases (19), and protein synthesis. Changes of protein synthesis were extensively studied at the tissue level in numerous animal models of acute injury such as trauma, sepsis, or pure inflammation (e.g., turpentine). Although dependent in part on the type of injury, the most typical changes included a depressed muscle protein synthesis (5, 10) and an increased synthesis of total liver proteins (5, 11, 24, 31) and of positive acute-phase proteins (18, 27, 31). Synthesis of negative acute-phase proteins (e.g., albumin) decreases in some (4, 26, 27) if not all (18, 31) studies, and its gene expression is depressed (21, 22). Finally, modification of protein synthesis in other tissues, such as gut, is more controversial (24, 11).

However, the clinical situations differ from animal models with respect to their duration. Whereas intensive care patients frequently exhibit severe inflammation and protein losses for days or weeks, animal studies are performed 1-5 days (at the most) after injury and thus might not be representative of what occurs in humans. Furthermore, few data exist for patients; although some studies have examined whole body protein synthesis (e.g., Ref. 14) and, more occasionally, muscle (13) and fibrinogen or fibronectin synthesis (29), there is no comprehensive study of these modifications in the same patients. In particular, data on albumin synthesis are extremely scarce (22). On the basis of animal studies, albumin synthesis is widely believed to decrease (1).

Therefore, the aim of this study was to assess in critically ill patients the modifications of protein synthesis, with simultaneous measurements at the whole body level and in muscle- and liver-derived proteins. For liver-derived proteins, we measured the synthesis of both a positive (fibrinogen) and negative (albumin) acute-phase protein. We chose to study severe head-injured patients for the following reasons: 1) they are known to experience a severe muscle loss, 2) they constitute a rather homogeneous group receiving a standardized treatment, and 3) they have a well-characterized and severe inflammatory response (20) even in the absence of sepsis. These patients were compared with a group of matched healthy subjects receiving identical nutritional intakes. The data on the proteolytic systems expression in the muscle of these patients have been published previously (19).

    MATERIALS, SUBJECTS, AND STUDY PROTOCOL
Top
Abstract
Introduction
Materials
Results
Discussion
References

Materials, subjects, and protocol were previously described in detail (19). Briefly, six patients with exclusive (no sepsis) and severe head traumas were compared with five healthy volunteers matched for age and body mass index. Patients were studied on day 8 after admission, while they were receiving continuous enteral nutrition for at least 3 days (Nutrison E+, Nutricia, The Netherlands, 39 ± 2 kcal · kg-1 · day-1 and 1.49 ± 0.09 g protein · kg-1 · day-1, means ± SE). A primed continuous (0.17 µmol · kg-1 · min-1) infusion of L-[1-13C]leucine (Mass Trace, Somerville, MA) was given through a central catheter for 10 h. The pool of bicarbonate was primed with 5 mg of NaH13CO3. Blood samples were taken at regular intervals, and muscle biopsies were taken before and at the end of the infusion. Indirect calorimetry was performed throughout the study using a Deltatrac (Datex, Geneva, Switzerland) connected to the respirator. Expired gas samples were taken in a Douglas bag at the exhaust of the respirator during 5 min at the same times as the blood samples. Breath samples were then transferred into Vacutainers (Becton-Dickinson, Grenoble, France). In addition, blood samples were also taken to measure plasma albumin, fibrinogen, orosomucoid, C-reactive protein, haptoglobin, and cytokines at days 4 and 8. Daily 24-h urinary excretion of cortisol (day 8) and nitrogen (from day 5 to day 7) were measured.

The isotopic study was performed in the control subjects in a similar manner. The enteral diet (34 ± 2 kcal · kg-1 · day-1 and 1.40 ± 0.09 g protein · kg-1 · day-1) was given only during the 10 h of the tracer infusion. The infusion rate of L-[1-13C]leucine was 0.10 ± 0.01 µmol · kg-1 · min-1. Indirect calorimetry was performed with the same device with the use of a canopy.

Analytic methods. Plasma 13C enrichments of leucine and ketoisocaproate (KIC) were determined as previously described (19). 13C enrichments of CO2 were measured by gas chromatography-isotope ratio mass spectrometry (GC-IRMS, Microgas, Fisons Instruments, Middlewich, UK). In two additional control subjects, it was verified that the diet used in the controls (which was made with potato maltodextrin) did not modify the natural 13C abundance in the breath (data not shown). In the patients who received maltodextrins made from corn, the basal 13C abundance was higher but was stable throughout the study, since this diet had been continuously administered for at least 3 days before the isotopic study.

Incorporation of [13C]leucine into the muscle proteins was measured by GC-combustion-IRMS (Isochrom, Fisons Instruments) according to Yarasheski et al. (32) with slight modifications. Briefly, 10-15 mg of muscle were powdered in liquid nitrogen and homogenized in trichloroacetic acid (TCA). The protein pellet was washed with TCA, hydrolyzed, filtered, and dried. N-acetyl propyl derivatives of leucine were separated from other amino acids onto a nonpolar GC column, and the leucine peak was directed through the furnace, where combustion in CO2 occurred. CO2 was then directed toward the IRMS in alternation with pulses of reference CO2 gas. Each sample was injected five to six times, and the mean coefficient of variation (CV) of replicates was 8% (range 4-11%). Standard curves covering a range of similar enrichments (0-0.005 atom percent excess, r2 >=  0.99) were run simultaneously. [13C]leucine enrichments in albumin and fibrinogen were also determined by GC-combustion-IRMS, as previously described (9). Purity of the isolated fractions was checked by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in both controls and patients (data not shown). Plasma protein (except fibrinogen) concentrations were measured by immunonephelometry. Fibrinogen concentration was determined by a turbidimetric assay (Biodirect, Les Ulis, France).

Calculations. Whole body leucine flux and oxidation were calculated at steady state, using the plasma [13C]KIC enrichment as the precursor pool. CO2 recovery factors of 0.82 in the controls and 0.90 (30) in the patients were used. Nonoxidative leucine disposal, an index of whole body protein synthesis, was the difference between flux and oxidation. Leucine balance was calculated as leucine intake, including the tracer infusion rate minus oxidation.

Muscle fractional synthesis rate (FSR, in %/day) was calculated as the ratio between the [13C]leucine incorporation in muscle (i.e., enrichment at time 10 h minus natural abundance at time 0) and the plasma [13C]KIC enrichment at plateau, multiplied by 2.4. The [13C]leucine incorporation rate into albumin and fibrinogen was calculated between time 6 and 10 h by least square regression analysis. FSRs were then obtained by dividing the slopes of incorporation (corrected for 24 h) by the plasma [13C]KIC enrichment at plateau. Absolute synthesis rates (ASR, in mg protein · kg-1 · day-1) were then calculated as FSR (%/day) times plasma albumin or fibrinogen concentrations (mg/ml) times plasma volume (ml/kg). The latter was calculated from the estimated blood volume (69 ml/kg in men, 65 ml/kg in women) (17) and the measured hematocrit.

Statistical analysis. All values are expressed as means ± SE. Between groups comparisons were made by two-tailed unpaired t-tests. Data in Table 1 (controls and trauma patients at day 4 and day 8) were compared by analysis of variance, followed by a Scheffé test.

                              
View this table:
[in this window]
[in a new window]
 
Table 1.   Plasma protein concentrations in control subjects and in head-injured patients at days 4 and 8 after admission

    RESULTS
Top
Abstract
Introduction
Materials
Results
Discussion
References

All the patients were in negative nitrogen balance (19). Their energy expenditure was similar to that of the controls (31.9 ± 3.6 and 26.8 ± 1.2 kcal · kg-1 · day-1, not significant), and their respiratory quotient was higher (0.95 ± 0.04 and 0.84 ± 0.01, P < 0.05). As shown in Table 1, patients had a severe biological inflammatory response increasing from day 4 to day 8, as assessed by high plasma levels of C-reactive protein, orosomucoid, haptoglobin, and fibrinogen. By contrast, plasma albumin concentrations decreased in the patients, the decrease being significant only at day 8. Plasma levels of interleukin-1beta (IL-1beta ) and interleukin-6 (IL-6), but not of tumor necrosis factor (TNF), were elevated, and so were cortisoluria (19). Hematocrit at day 8 was lower in the patients (31 ± 2%) than in the controls (46 ± 1%, P < 0.001), and the calculated plasma volume was therefore higher in the patients than in the controls (46 ± 1 vs. 37 ± 1 ml/kg, respectively, P < 0.001).

Plateaus of leucine and KIC enrichments were obtained in all subjects after 2 h of infusion. Whole body leucine flux was increased by 50% in the patients (P < 0.001), as previously reported (19). Leucine oxidation was doubled (P < 0.01), and nonoxidative leucine disposal increased by 28% in patients (P < 0.02; Table 2). Leucine balance was positive during feeding in the controls, whereas it remained negative in the patients (P < 0.01). Similar qualitative results were obtained when leucine enrichments were used instead of KIC enrichments (data not shown).

                              
View this table:
[in this window]
[in a new window]
 
Table 2.   Whole body leucine kinetics measured by isotopic dilution during a 10-h constant infusion of L-[1-13C]leucine in enterally fed control subjects and head-injured patients 8 days after admission

Muscle FSR was sharply decreased in the patients compared with the controls (1.94 ± 0.23 vs. 0.86 ± 0.21%/day, P < 0.01). The incorporation of the tracer into albumin and fibrinogen is displayed on Fig. 1 for both the control subjects and the patients. The slopes of incorporation were all linear (mean r2 = 0.98 ± 0.01, range 0.91-0.99). They were greater in the patients than in the controls, whereas the plateaus of plasma KIC enrichments were similar in both groups. Therefore, the FSR of fibrinogen and albumin were higher in the patients, as shown in Fig. 2 (fibrinogen FSR: 15.1 ± 1.7 vs. 28.1 ± 2.2 %/day, P < 0.001; albumin FSR: 7.3 ± 0.4 vs. 11.4 ± 1.0 %/day, P < 0.01 in the controls and patients, respectively). Fibrinogen ASR was eight times higher in the patients (75 ± 13 mg · kg-1 · day-1) than in the controls (9 ± 1 mg · kg-1 · day-1) (P < 0.001). Despite the decreased albumin concentration, albumin ASR was still elevated in the patients (133 ± 14 vs. 91 ± 5 mg · kg-1 · day-1, P < 0.02).


View larger version (14K):
[in this window]
[in a new window]
 
Fig. 1.   Rates of incorporation of L-[1-13C]leucine into albumin (A) and fibrinogen (B) in head trauma patients (bullet ) and in control subjects (open circle ). [13C]leucine enrichments into proteins were measured by isotope ratio mass spectrometry during a 10-h constant intravenous infusion of L-[1-13C]leucine. C: plateau of 13C enrichment into plasma ketoisocaproate (KIC), representative of intracellular free leucine enrichment. All data are means ± SE. APE, atom percent excess.


View larger version (21K):
[in this window]
[in a new window]
 
Fig. 2.   Plasma concentrations, fractional synthesis rates (FSRs), and absolute synthesis rates (ASRs) of albumin (A) and fibrinogen (B) in head trauma patients (filled bars) and in control subjects (open bars). FSRs were determined by incorporation of [13C]leucine into proteins during a constant 10-h infusion of L-[1-13C]leucine, using plasma KIC enrichment as precursor pool. ASRs were calculated as FSR × plasma concentration × plasma volume. All data are means ± SE; * P < 0.02, dagger  P < 0.01, ddager  P < 0.001.

    DISCUSSION
Top
Abstract
Introduction
Materials
Results
Discussion
References

The patients in this study were head trauma patients, and they might not be representative of all the trauma situations, due to the unique locus of injury, but, as far as acute inflammation is concerned, their inflammatory profiles are very similar to those observed in other traumas or sepsis. It is possible that factors other than the head trauma itself contributed to the observed changes. For example, prolonged immobilization reduces muscle protein synthesis (16). Also, central catheters can induce inflammation in rats (11). However, for ethical reasons it was not possible to fit the control subjects with such a catheter, and, furthermore, a full surgical procedure is needed in rats, whereas catheters are implanted percutaneously in a few minutes in humans.

Whole body protein metabolism was assessed with the well-established [13C]leucine method, and our data confirm a recent study showing an increased whole body synthesis 48 h after head injury (14). For leucine oxidation calculations, we used a recovery factor of 0.9, which was measured in patients, including those with head trauma, with an artificial ventilation very similar to that of the patients in our study (30). In any case, using any factor between 0.82 and 1.0 does not affect our conclusions, given the large difference of leucine oxidation between the patients and controls.

Whole body protein synthesis reflects the sum of protein synthesis rates of all tissues and, in particular, of muscle and liver, which together account for the major part of the whole body protein synthesis rate. In muscle, plasma KIC enrichments slightly overestimate both leucyl tRNA and intracellular free leucine enrichments (7), and our FSR is thus likely to be slightly underestimated. Although this problem could have been overcome by using the flooding dose method, thisapproach does not allow simultaneous measurements of whole body protein synthesis and could possibly modify protein synthesis in itself (25). Also, the large difference of muscle FSR between the controls and the patients was possibly overestimated because of the higher muscle proteolysis in the patients (19), probably leading to a higher dilution of the label in the precursor pool. However, the leucyl tRNA enrichment would have to be as low as 36% of the KIC enrichment to fully compensate for this difference, which is highly unlikely. Furthermore, our observation is consistent with animal and human studies performed, with the flooding dose method showing that sepsis or inflammation in rats (5, 10) or surgery in humans (13) all decrease muscle FSR. Cytokines and glucocorticoids were probably responsible for this decrease. IL-1beta depresses muscle protein synthesis (5), TNF inhibits amino acid uptake [this effect being mediated in part by glucocorticoids (33)], and finally, IL-1 receptor antagonist prevents the sepsis-induced inhibition of synthesis (10). Our patients did exhibit hypercortisoluria and high plasma levels of IL-1beta , but we failed to show increased TNF levels, which are very transient and which probably would have occurred early after admission.

The dramatic increase of fibrinogen FSR and ASR was expected, fibrinogen being taken as a paradigm for the positive acute-phase proteins, and Thompson et al. (29) reported similar increases in three traumatized patients. This is also consistent with the increased expression of the fibrinogen gene in rat liver after surgery (21). IL-6 is considered as the cytokine predominantly involved in the increased fibrinogen synthesis (8). Although the rate of synthesis of other positive acute-phase proteins was not measured, the dramatic increase of their concentrations suggests that their synthesis was stimulated as well.

The issue of albumin synthesis is more complicated, since we observed increased FSR (×1.6) and ASR (×1.5) despite hypoalbuminemia. Albumin concentration always decreases in severe inflammatory, septic, or injured patients and animals; for example, it was shown to reach a nadir 7 days after injury in a large series of head-injured patients (20). Hypoalbuminemia might be due to a reduced synthesis or an increased degradation or an alteration of the transcapillary escape rate. The former hypothesis is the most widely accepted (1) on the basis of numerous animal studies showing a decreased albumin gene expression, occurring rapidly after various aggressions (e.g., Refs. 21 and 22). However, actual measurements of albumin synthesis are less consistent, showing either a decrease (4, 22, 26, 27) or an increase (18, 31). A reduced dietary intake also participates in the depressed albumin synthesis (2). Data in humans are extremely scarce. Moshage et al. (22) reported, in four normally fed patients with various diseases and profound hypoalbuminemia, a 25% decrease of albumin ASR but an unchanged FSR.

Thus there is little doubt that an acute inflammation initially depresses albumin gene expression and synthesis, which might well have occurred in our patients and been responsible for the initiation of hypoalbuminemia. However, the hypoalbuminemia observed later on is actually associated with an increased albumin synthesis. This suggests a biphasic pattern (decrease, then increase) for albumin synthesis. Such a response was demonstrated in a prolonged animal model of sepsis in which albumin synthesis was measured 16 (26) and 96 h (31) after injury. Glucocorticoids are known to increase albumin synthesis in vivo (12) and to upregulate albumin gene expression in vitro (3). In our patients, cytokine levels (IL-6, IL-1beta ) were stable between days 4 and 8, whereas cortisoluria doubled over the same period (19). Therefore, we could speculate that glucocorticoids mediate the secondary increase of albumin synthesis. Alternatively, plasma amino acids and particularly leucine concentrations were possibly elevated in the patients due to their higher proteolysis (and to the slightly higher rate of tracer infusion). They could stimulate albumin synthesis, as demonstrated in cancer patients fed with a branched-chain amino acid formula (28). The persistent hypoalbuminemia could be explained by an escape of plasma albumin in the extravascular space. In this respect, the albumin transcapillary escape rate was found to be increased by 50-300% in critically ill (15) and in infected patients (6). Also, IL-1beta was reported to dramatically increase albumin transfer across endothelial cells (20). However, the positive correlation between albumin levels and its transcapillary escape rate reported by Ballmer et al. (6) suggests that other mechanisms, such as an increased degradation rate, could also contribute to hypoalbuminemia in the acute-phase response.

In conclusion, we demonstrated that, in continuously fed humans with severe inflammation, there are opposite changes in the synthesis of muscle and acute-phase hepatic protein, including albumin. This could be interpreted as a necessity for the liver to be supplied with large amounts of amino acids for sustaining the acute-phase hepatic response, the amino acids being derived from increased breakdown and decreased synthesis in muscle. This is different from what is observed in rats with moderate inflammation, in which liver synthesis increases while muscle is unaffected (24). Also, it was recently shown that the reversal of muscle loss by cytokine antagonists does not affect hepatic synthesis in septic rats (11). Therefore, further studies are needed both in humans and animal models to establish whether or not there is a causal relationship between changes in muscle and liver protein synthesis during severe inflammation.

    ACKNOWLEDGEMENTS

We thank the staff of the Intensive Care Unit, J. Prugnaud, L. Morin, M. Genest, P. Rousset, E. Verdier, G. Manlhiot, and J. Moinard for expert technical assistance, G. Beaujon for the cytokine assays, and S. Samuels for helpful comments. We also thank Nutricia France for providing the enteral products. This study was funded by grants from Institut National de la Recherche Agronomique, Université d'Auvergne and Région Auvergne.

    FOOTNOTES

Address for reprint requests: B. Beaufrère, Laboratoire de Nutrition Humaine, BP 321, 63009 Clermont-Ferrand Cedex 1, France.

Received 10 April 1997; accepted in final form 8 July 1997.

    REFERENCES
Top
Abstract
Introduction
Materials
Results
Discussion
References

1.   Aldred, A. R., and G. Schreiber. The negative acute phase proteins. In: Acute Phase Proteins. Molecular Biology, Biochemistry and Clinical Applications, edited by A. Mackiewicz, I. Kushner, and H. Baumann. Boca Raton, FL: CRC, 1993, p. 21-38.

2.   Andersson, C. E., I. C. Lönnrot, L. J. Gelin, L. L. Modawer, and K. G. Lundholm. Pretranslational regulation of albumin synthesis in tumor-bearing mice. The role of anorexia and undernutrition. Gastroenterology 100: 938-945, 1991[Medline].

3.   Andus, T., T. Geiger, T. Hirano, T. Kishimoto, and P. C. Heinrich. Action of recombinant human interleukin 6, interleukin 1beta and tumor necrosis factor alpha  on the mRNA induction of acute-phase proteins. Eur. J. Immunol. 18: 739-746, 1988[Medline].

4.   Ballmer, P. E., M. A. McNurlan, I. Grant, and P. J. Garlick. Down-regulation of albumin synthesis in the rat by human recombinant interleukin-1beta or turpentine and the response to nutrients. J. Parenter. Enteral Nutr. 19: 266-271, 1995.[Abstract]

5.   Ballmer, P. E., M. A. McNurlan, B. G. Southorn, I. Grant, and P. J. Garlick. Effects of human recombinant interleulin-1beta on protein synthesis in rat tissues compared with a classical acute-phase reaction induced by turpentine. Biochem. J. 279: 683-688, 1991[Medline].

6.   Ballmer, P. E., A. F. Ochsenbein, and S. Schütz-Hofmann. Transcapillary escape rate of albumin positively correlates with plasma albumin concentration in acute but not in chronic inflammatory disease. Metabolism 43: 697-705, 1994[Medline].

7.   Baumann, P. Q., W. S. Stirewalt, B. D. O'Rourke, D. Howard, and K. S. Nair. Precursor pools of protein synthesis: a stable isotope study in a swine model. Am. J. Physiol. 267 (Endocrinol. Metab. 30): E203-E209, 1994[Abstract/Free Full Text].

8.   Castell, J. V., M. J. Gomez-Lechon, M. David, R. Fabra, R. Trullenque, and P. C. Heinrich. Acute-phase response of human hepatocytes: regulation of acute-phase protein synthesis by interleukin-6. Hepatology 12: 1179-1186, 1990[Medline].

9.   Cayol, M., I. Tauveron, F. Rambourdin, J. Prugnaud, P. Gachon, P. Thieblot, J. Grizard, and C. Obled. Whole-body protein turnover and hepatic protein synthesis are increased by vaccination in man. Clin. Sci. (Colch.) 89: 389-396, 1995[Medline].

10.   Cooney, R., E. Owens, C. Jurasinski, K. Gray, J. Vannice, and T. Vary. Interleukin-1 receptor antagonist prevents sepsis-induced inhibition of protein synthesis. Am. J. Physiol. 267 (Endocrinol. Metab. 30): E636-E641, 1994.

11.   Cooney, R. N., E. Owens, D. Slaymaker, and T. C. Vary. Prevention of skeletal muscle catabolism in sepsis does not impair visceral protein metabolism. Am. J. Physiol. 270 (Endocrinol. Metab. 33): E621-E626, 1996[Abstract/Free Full Text].

12.   De Feo, P., F. F. Horber, and M. W. Haymond. Meal stimulation of albumin synthesis: a significant contributor to whole body protein synthesis in humans. Am. J. Physiol. 263 (Endocrinol. Metab. 26): E794-E799, 1992[Abstract/Free Full Text].

13.   Essén, P., M. A. McNurlan, J. Wernerman, E. Vinnars, and P. J. Garlick. Uncomplicated surgery, but not general anesthesia, decreases muscle protein synthesis. Am. J. Physiol. 262 (Endocrinol. Metab. 25): E253-E260, 1992[Abstract/Free Full Text].

14.   Flakoll, P. J., L. S. Wentzel, and S. A. Hyman. Protein and glucose metabolism during isolated closed-head injury. Am. J. Physiol. 269 (Endocrinol. Metab. 32): E636-E641, 1995[Abstract/Free Full Text].

15.   Fleck, A., F. Hawker, P. I. Wallace, G. Raines, J. Trotters, I. M. Ledingham, and K. C. Calman. Increased vascular permeability: a major cause of hypoalbuminemia in disease and injury. Lancet 1: 781-784, 1985[Medline].

16.   Gibson, J. N. A., D. Halliday, W. L. Morrison, P. J. Stoward, G. A. Hornsby, P. W. Watt, G. Murdoch, and M. J. Rennie. Decrease in human quadriceps muscle protein turnover consequent upon leg immobilization. Clin. Sci. (Colch.) 72: 503-509, 1987[Medline].

17.   Harrison, T. R. Principles of Internal Medicine. New York: McGraw-Hill, 1983, p. A1.

18.   Koj, A., and A. S. McFarlane. Effect of endotoxin on plasma albumin and fibrinogen synthesis rates in rabbits as measured by the 14C carbonate method. Biochem. J. 108: 137-146, 1968[Medline].

19.   Mansoor, O., B. Beaufrère, Y. Boirie, C. Rallière, D. Taillandier, E. Aurousseau, P. Schoeffler, M. Arnal, and D. Attaix. Increased mRNA levels for components of the lysosomal, Ca2+-activated, and ATP-ubiquitin-dependent proteolytic pathways in skeletal muscle from head trauma patients. Proc. Natl. Acad. Sci. USA 93: 2714-2718, 1996[Abstract/Free Full Text].

20.   McClain, C. J., B. Hennig, L. G. Ott, S. Goldblum, and B. Young. Mechanisms and implications of hypoalbuminemia in head-injured patients. J. Neurosurg. 69: 386-392, 1988[Medline].

21.   Milland, J., A. Tsykin, T. Thomas, A. R. Aldred, T. Cole, and G. Schreiber. Gene expression in regenerating and acute-phase rat liver. Am. J. Physiol. 259 (Gastrointest. Liver Physiol. 22): G340-G347, 1990[Abstract/Free Full Text].

22.   Moshage, H. J., J. A. M. Janssen, J. H. Franssen, J. C. M. Hafkenscheid, and S. H. Yap. Study of the molecular mechanism of decreased liver synthesis of albumin in inflammation. J. Clin. Invest. 79: 1635-1641, 1987[Medline].

23.   Perlmutter, D. H., C. A. Dinarello, P. I. Punsal, and H. R. Colten. Cachectin/tumor necrosis factor regulates hepatic acute-phase gene expression. J. Clin. Invest. 78: 1349-1354, 1986[Medline].

24.   Preedy, V. R., L. Paska, P. H. Sugden, P. S. Schofield, and M. C. Sugden. The effects of surgical stress and short-term fasting on protein synthesis in vivo in diverse tissues of the mature rat. Biochem. J. 250: 179-188, 1988[Medline].

25.   Rennie, M. J., K. Smith, and P. W. Watt. Measurement of human tissue protein synthesis: an optimal approach. Am. J. Physiol. 266 (Endocrinol. Metab. 29): E298-E307, 1994[Abstract/Free Full Text].

26.   Sax, H. C., M. A. Talamini, P. O. Hasselgren, L. Rosenblum, C. K. Hogh, and J. E. Fischer. Increased synthesis of secreted hepatic proteins during abdominal sepsis. J. Surg. Res. 44: 109-116, 1988[Medline].

27.   Schreiber, G., G. Howlett, M. Nagashima, A. Miellership, H. Martin, J. Urban, and L. Kotler. The acute phase response of plasma protein synthesis during experimental inflammation. J. Biol. Chem. 257: 10271-10275, 1982[Free Full Text].

28.   Tayek, J. A., B. R. Bistrian, D. J. Hehir, R. Martin, L. L. Moldawer, and G. L. Blackburn. Improved protein kinetics and albumin synthesis by branched chain amino acid enriched total parenteral nutrition in cancer cachexia. A prospective randomized crossover trial. Cancer 58: 147-157, 1986[Medline].

29.   Thompson, C., F. A. Blumenstock, T. M. Saba, P. J. Feustel, J. E. Kaplan, J. B. Fortune, L. Hough, and V. Gray. Plasma fibronectin synthesis in normal and injured humans as determined by stable isotope incorporation. J. Clin. Invest. 84: 1226-1235, 1989[Medline].

30.   Tissot, S., B. Delafosse, S. Normand, Y. Bouffard, G. Annat, J. P. Viale, C. Pachiaudi, J. P. Riou, and J. Motin. Recovery of [13C] bicarbonate as respiratory 13CO2 in mechanically ventilated patients. Am. J. Clin. Nutr. 57: 202-206, 1993[Abstract].

31.   Von Allmen, D., P. O. Hasselgren, and J. E. Fischer. Hepatic protein synthesis in a modified septic rat model. J. Surg. Res. 48: 476-480, 1990[Medline].

32.   Yarasheski, K. E., K. Smith, M. J. Rennie, and D. M. Bier. Measurement of muscle protein fractional synthetic rate by capillary gas chromatography/combustion isotope ratio mass spectrometry. Biol. Mass Spectrom. 21: 486-490, 1992[Medline].

33.   Zamir, O., P. O. Hasselgren, D. Van Allmen, and J. E. Fischer. Effect of tumor necrosis factor or interleukin-1 on muscle amino acid uptake and the role of glucocorticoids. Surg. Gynecol. Obstet. 177: 27-32, 1993[Medline].


AJP Endocrinol Metab 273(5):E898-E902
0193-1849/97 $5.00 Copyright © 1997 the American Physiological Society