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Clinical and Diagnostic Laboratory Immunology, November 1999, p. 844-850, Vol. 6, No. 6
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Changes in Endotoxin-Binding Proteins during Major
Elective Surgery: Important Role for Soluble CD14 in Regulation of
Biological Activity of Systemic Endotoxin
Naoki
Hiki,1,*
Dieter
Berger,2
Mieke A.
Dentener,3
Yoshikazu
Mimura,1
Wim A.
Buurman,4
Claus
Prigl,2
Manuela
Seidelmann,2
Eiichi
Tsuji,1
Michio
Kaminishi,1 and
Hans
G.
Beger2
Department of General Surgery, University of
Ulm, Ulm, Germany2; Department of
Surgery, The University of Tokyo, Tokyo, Japan1;
and Department of Pulmonology,3 and
Department of Surgery,4 University
Maastricht, Maastricht, The Netherlands
Received 15 March 1999/Returned for modification 21 June
1999/Accepted 29 July 1999
 |
ABSTRACT |
Assessment of circulating endotoxin during the perioperative
period, which is only demonstrated by the Limulus amebocyte
lysate (LAL) test, may be modulated by several endotoxin-binding
proteins. Endotoxin-neutralizing capacity (ENC) and the plasma levels
of soluble CD14 (sCD14), lipopolysaccharide-binding protein, and bactericidal/permeability-increasing protein (BPI) were determined in
40 patients 6 h prior to skin incision for major abdominal surgery. The bioactivity of plasma endotoxin was tested by the polymyxin B-inhibited stimulatory activity of the plasma samples on
healthy monocytes as measured by the release of tumor necrosis factor
alpha. Plasma endotoxin levels in almost all patients increased from
0.05 ± 0.01 to 0.23 ± 0.03 experimental units (EU) per ml (P < 0.001); more specifically, 17 of 40 samples
showed endotoxin levels of greater than 0.2 EU per ml and corresponding
reductions in ENC. Soluble CD14 plasma levels were decreased from
5.6 ± 0.3 to 4.6 ± 0.3 µg per ml (P < 0.05). ENC was strongly correlated with the sCD14 plasma concentration
throughout the period of observation. The addition of
sCD14-neutralizing monoclonal anti-sCD14 antibodies reduced ENC both
pre- and postoperatively. No correlation could be established between
ENC and the plasma levels of BPI, high-density lipoproteins, or
low-density lipoproteins determined by measuring the concentrations of
apoprotein A and apoprotein B. Biologically active endotoxin was found
in only 6 of 17 samples with endotoxin levels greater than 0.2 EU per
ml in the LAL test. These samples could be characterized by their
perioperative loss of at least 35% of their sCD14. No change in sCD14
was detected in the remaining 11 samples. The perioperative loss of ENC
is partly caused by the loss of sCD14 resulting from its consumption by
endotoxin reaching the bloodstream. This study demonstrated the role of sCD14 on the bioactivity of circulating endotoxin in a human model of
endotoxemia after major abdominal surgery.
| |
INTRODUCTION |
A number of cell types, including
hepatocytes (15, 33), local macrophages (16, 26,
40), and granulocytes (35, 36), have cellular
endotoxin-neutralizing activity mediated via well-characterized
mechanisms of lipopolysaccharide (LPS) inactivation. In addition to the
cellular endotoxin neutralization system, soluble endotoxin-binding and
-neutralizing factors that reduce the harmful action of circulating
endotoxin are also present in plasma. Early studies showed that plasma
itself is a potent inhibitor of endotoxin-mediated phenomena such as
pyrogenicity (41, 42). Later experiments showed that several
plasma proteins may bind endotoxin either in a specific or unspecific
manner, which was assumed to be associated with an alteration of
aspects of endotoxin bioactivity (14, 31, 45). Most
recently, the soluble form of the endotoxin receptor CD14 (sCD14) was
demonstrated to mediate the LPS-neutralizing action of high-density
lipoproteins (22, 23, 47). Plasma sCD14 levels are
increased during septic diseases (7, 29, 30) as well as
after multiple-trauma and burn injuries (28).
Bactericidal/permeability-increasing protein (BPI), a neutrophil
granule protein, diminishes the bioactivity of LPS in vitro (1,
24) and in vivo (13, 44) and has been shown to
increase significantly during sepsis (8, 17). The
LPS-binding protein (LBP) first catalytically transfers an LPS monomer
to a binding site on sCD14 (20), and the resulting LPS-sCD14
complexes diffuse readily, breaking LPS into lipoprotein particles
(47-49). LBP is a classical acute phase protein, which is
strongly enhanced during acute inflammatory responses (17, 19).
The endotoxin-neutralizing capacity (ENC) of plasma can be easily
determined by a direct Limulus amebocyte lysate (LAL) test without heat inactivation of the inhibitors present in plasma (4). Our previous studies showed that ENC was decreased
significantly during aseptic abdominal surgery, which is associated
with impending complications due to infection (4). Elective
aseptic abdominal surgery represents a human model characterized by a
significant and reproducible endotoxemia and a well-defined acute phase
reaction (5, 6, 12, 37, 46). Although there are some
indications that circulating endotoxin has bioactivity during the
postoperative (5, 32) and posttraumatic courses
(25), its pathophysiological relevance is far from being
generally accepted. The complex nature of cellular and soluble
neutralizing mechanisms may account for the observation that high
endotoxin levels are not invariably correlated with clinical signs. We
propose that the endotoxin-binding proteins, and sCD14 in particular,
determine the biological activity of translocated endotoxin during surgery.
In this study, we aimed to (i) evaluate the sCD14, LBP, BPI, and
endotoxin plasma levels and the ENC of the plasma during major elective
abdominal surgery, (ii) estimate the relationship of sCD14, LBP, and
BPI on ENC, and (iii) estimate the biological activity of perioperative
plasma assessed by the effect of plasma on monocyte tumor necrosis
factor alpha (TNF-
) production in response to LPS.
| |
MATERIALS AND METHODS |
The local ethical committee of the University of Ulm approved
this study, and blood donors gave informed consent for research.
Patients and a healthy volunteer.
Forty patients undergoing
elective major abdominal surgery (gastrectomy, n = 5;
pancreatectomy, n = 28; colectomy, n = 7) were enrolled in the present study (Table
1). Exclusion criteria were as follows:
age less than 18 years, liver cirrhosis, pregnancy, preexisting renal
insufficiency requiring hemodialysis, immunosuppression, or acute
inflammatory disease which was checked by plasma cyclic AMP receptor
protein levels (cutoff level of cyclic AMP receptor protein, <100 mg
per liter). To rule out the bacteriocidal and bacteriocytic effects of
antibiotic therapy, we excluded patients who were given any antibiotics
within 6 h before or after the skin incision. We applied monocytes
from one healthy volunteer for the stimulation assay. Before starting
the experiment, 10 healthy volunteers were checked for responsiveness
to endotoxin stimulation by checking TNF- secretion. Afterwards, we
selected a volunteer with average responsiveness as determined by
TNF- secretion.
Preparation of blood samples.
Blood samples were collected
prior to and 6 h after skin incision by puncture of the cubital
vein under sterile conditions. To exclude the influence of anesthesia,
the preoperative samples were collected after the induction of
anesthesia but before the surgery. The time point of 6 h after
skin incision was selected because the results of our recent study
revealed that this time point would most likely yield peak plasma
endotoxin levels (25). The blood was anticoagulated with 10 IU of sodium heparin per ml of blood. Platelet-poor autologous plasma
was prepared by centrifugation at 2,000 × g for 10 min. Care was taken to prevent contamination of the plasma samples with
polymorphonuclear leukocytes, which may release BPI even after freezing
and thawing (9). Hemolytic plasma samples were excluded to
minimize artificial BPI release (38). Samples were stored at
70°C for up to 4 weeks in multiple aliquots. All tubes used in
blood collection and analysis were certified to be endotoxin free.
Determination of endotoxin content.
Endotoxin plasma levels
were determined by using a two-step, endpoint micromethod as described
previously in detail (3). The unknown samples were
pretreated by heat inactivation for 10 min at 75°C and were incubated
with the lysate (Charles River Endosafe, Sulzfeld, Germany) for 30 min
at 37°C. After adding 5-mmol/ml chromogenic substrate (Pefachrome
from LPS, Sinntal-Oberzell, Germany), samples were further incubated
for 3 min at 37°C. The reaction was stopped, and the endotoxin
content was quantified according to a simultaneously established
standard curve in pyrogen-free plasma.
Estimation of ENC.
The ENC of plasma, expressed as endotoxin
recovery, was measured by using the LAL test and has been recently
described in detail (4). The method principally relies on
the determination of the recovery of exogenously added endotoxin to
plasma samples. In contrast to the estimation of endogenous endotoxin,
inactivation of the plasma samples was omitted. Ten microliters of a
standard endotoxin of Salmonella abortus subsp.
equi (1,000 EU/ml) (NP3; Pyroquant Co., Moerfelden-Walldorf,
Germany) were added to 90 µl of plasma. After incubation at 24°C
for 30 min, the sample was diluted with 900 µl of pyrogen-free water
(final concentration, 10 EU/ml). The endotoxin recovery was determined
as described above except that the standard curve was established in
pyrogen-free water. Intra- and interassay variation coefficients
amounted to 6.5 and 7.2%, respectively, as ascertained in 30 single
determinations. In experiments designed to determine the role of sCD14,
the plasma samples were preincubated with 10 µg of the monoclonal
anti-CD14 antibody MEM-18 per ml, (kindly provided by V. Horesji,
Institute of Organic Chemistry and Biochemistry, Prague, Czech
Republic) (2) for 20 min at 24°C before LPS was added.
Endogenous endotoxin levels of all samples were subtracted from the
recovery data.
Determination of albumin, apo A, and apo B plasma levels.
The plasma levels of albumin, apoprotein A (apo A), and apoprotein B
(apo B) were determined by a nephelometer (200 analyzer; Behring Co.,
Liederbach, Germany).
ELISA assays.
Plasma TNF- was quantified with a
commercially available enzyme-linked immunosorbent assay (Immunotech,
Hamburg, Germany). Soluble CD14 was measured by using a sandwich ELISA
with two monoclonal antibodies against CD14 (IBL, Hamburg, Germany).
Plasma samples which were diluted 1:200 with phosphate-buffered saline
(PBS) were assayed in ELISA following manufacturer's instructions.
Plasma BPI and LBP levels were determined by using a sandwich ELISA as reported elsewhere in detail (9). In short, microtiter
plates were coated with human-BPI-specific monoclonal antibody 4E3 or with polyclonal anti-human LBP immunoglobulin G (IgG). Washing and
dilution buffers for BPI and LBP determination contained 80 mM and 40 mM MgCl2, respectively. Mg++ ions were added to
prevent the influence of LPS on BPI or LBP measurement. Human
recombinant BPI or recombinant LBP (provided by M. Marra, InCyte, Palo
Alto, Calif.) was used for the standard curve. Samples diluted in the
above buffer (1:2 for BPI, 1:2,000 for LBP) were assayed. Biotinylated
polyclonal rabbit anti-human BPI IgG and biotinylated rabbit anti-human
LBP IgG were used as secondary antibodies, followed by visualization
using peroxidase-conjugated streptavidin (Dakopatts, Glostrup,
Denmark). The levels of detection of both assays were 200 pg/ml.
Isolation of monocytes.
Peripheral blood mononuclear cells
(PBMCs) were obtained from 10 healthy male donors. Venous blood mixed
with 10 IU of sodium heparin was separated in a 50-ml polystyrene tube
with a porous filter disk (LuecoSep; Greiner, Frickenhausen, Germany)
using Ficoll-Paque solution (Seromed, Berlin, Germany) at
450 × g for 20 min. PBMCs were washed three times with
PBS and then finally suspended at 2 × 106 PBMCs per
ml of RPMI 1640 (GIBCO, Eggenstein, Germany) containing 10% autologous
plasma. Monocytes were separated from lymphocytes by adherence (12 h at
37°C) to 12-well polystyrene plates (Greiner). After removal of
nonadherent cells, monocytes were extensively washed with PBS
containing 5% autologous plasma to remove residual nonadherent cells.
Assessment of biological activity of LPS in surgical plasma
samples.
The bioactivity of LPS in pre- and postsurgical plasma
samples was tested by incubating the plasma, diluted to 50% with RPMI 1640, with monocytes of healthy volunteers in the presence or absence
of polymyxin B (Pfizer, Karlsruhe, Germany). Plasma samples were
incubated for 20 min with or without 5 µg of polymyxin B per ml at
room temperature, and subsequently 4 × 105 monocytes
were added. The cells were cultured at 37°C in a 5% CO2
atmosphere for 5 h. After incubation, the supernatant was collected and frozen at 70°C. In control experiments, we assessed that polymyxin B abolishes the bioactivity of 50 pg of
Escherichia coli O55:B5 (BioWhittaker, Walkersville, Md.)
per ml in monocytic cultures. In this experiment, a mixture containing
50% autologus plasma was used.
Statistical analysis.
Data were expressed as means ± standard errors (SEs). Statistical evaluations of continuous data were
performed by one-way analyses of variance and unpaired t
tests for intergroup differences. Differences were considered
significant at P < 0.05.
| |
RESULTS |
Endotoxin plasma levels and plasma endotoxin recovery.
We
previously demonstrated significant endotoxemia only at the time point
of 6 h after surgical stress in patients with multiple trauma
(25). Therefore, the time point of 6 h after skin
incision was selected for this study design. As shown in Fig.
1A, preoperative endotoxin plasma levels
were 0.05 ± 0.01 EU/ml (normal; <0.07 EU/ml). Six hours after
the skin incision, a significant increase to 0.23 ± 0.03 EU/ml
was observed (P < 0.001). The plasma endotoxin levels
did not increase in 4 of 40 patients (10%). The recovery of
exogenously added endotoxin (10 EU/ml) to pre- and postoperative plasma
samples is given in Fig. 1B. Endotoxin recovery increased from a mean
of 0.06 ± 0.01 to 0.31 ± 0.03 EU/ml (P < 0.001) in each of the 40 patients. Endogenous endotoxin levels of
all samples were subtracted from the recovery data.
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FIG. 1.
(A) Endotoxin plasma levels after major abdominal
surgery. Endotoxin plasma levels are demonstrated on the y
axis. The time points (preoperative [preop.] and postoperative
[postop.]) are given on the x axis. (B) ENC after major
abdominal surgery. Levels of endotoxin recovery are depicted on the
y axis. The time points (preop. and postop.) are shown on
the x axis.
|
|
Kinetics of sCD14, LBP, and BPI levels during elective abdominal
surgery.
The plasma concentration of sCD14 (Fig.
2A) decreased perioperatively from
5.6 ± 0.3 µg/ml to 4.6 ± 0.3 µg/ml (P < 0.05). A decrease of plasma LBP levels (5.7 ± 0.8 to
4.0 ± 0.5 µg/ml; P < 0.05) was observed (Fig.
2B). Plasma BPI levels did not change during the observation period
(Fig. 2C). The plasma levels of albumin, apo A, and apo B were all
significantly decreased (Table 2).
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FIG. 2.
(A) Plasma sCD14 levels after major abdominal surgery.
The plasma sCD14 concentrations are given on the y axis. (B)
Plasma LBP levels after major abdominal surgery. The plasma LBP
concentrations are depicted on the y axis. (C) Plasma BPI
levels after major abdominal surgery. The plasma BPI concentrations are
shown on the y axis.
|
|
Relationship between ENC and endotoxin-binding proteins in
plasma.
A significant correlation was found between the sCD14
plasma level and the postoperative recovery of endotoxin (Fig.
3B) (r = 0.66; P < 0.0001).
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FIG. 3.
Correlation between ENC and sCD14. (A) Preoperative time
point. (B) Postoperative time point. Plasma sCD14 levels are given on
the x axis. Levels of endotoxin recovery are shown on the
y axis.
|
|
Plasma LBP values showed a negative correlation with endotoxin recovery
after surgical stress (Fig.
4B)
(
r =
0.60;
P < 0.0001).
Plasma BPI levels did
not correlate with endotoxin (data not shown).
There was no correlation
between albumin, apo A, and apo B plasma
levels and the recovery of
sCD14, LBP, BPI, or endotoxin.
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FIG. 4.
Correlation between ENC and LBP. (A) Preoperative time
point. (B) Postoperative time point. Plasma LBP levels are demonstrated
on the x axis. Levels of endotoxin recovery are depicted on
the y axis.
|
|
Figure
5 represents endotoxin recovery in
the presence or absence of MEM18. The addition of MEM18 significantly
increased
endotoxin recovery (
P < 0.01; change in
endotoxin recovery, 0.05
± 0.01 EU/ml) in the preoperative plasma
samples. A large, but
not significant, increase (
P = 0.06) in endotoxin recovery compared
to the MEM18 negative assay
was detected for postoperative samples
(change in endotoxin recovery,
0.12 ± 0.04 EU/ml).
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FIG. 5.
Effect of anti-CD14 monoclonal antibody (MEM18) on ENC.
Ten micrograms of MEM18 per ml was preincubated with plasma before the
determination of ENC. Levels of endotoxin recovery are depicted on the
y axis. The time points (preop. and postop.) are given on
the x axis.
|
|
Correlation of plasma sCD14 with the biological activity of
postoperative plasma.
In LAL tests, 17 of 40 (43%) postsurgical
plasma samples showed endotoxin levels which were all above 0.20 EU/ml.
These 17 samples were used to stimulate healthy monocytes in order to
evaluate bioactivity as determined by TNF- release (Fig.
6). Preoperative plasma did not
significantly stimulate the monocyte culture (data not shown). The
activity of 6 of the 17 postoperative plasma samples could be blocked
by the addition of 5 µg of polymyxin B per ml (P < 0.01) (Fig. 6A), indicating that biologically active endotoxin was
responsible for this plasma activity. The observation that the activity
of the other 11 plasma samples could not be blocked by polymyxin B
(Fig. 6B) indicates that the endotoxin present in these samples is not
biologically active but that other plasma components may be responsible
for the observed monocyte activation. The sCD14 content of these 6 of
the 17 samples decreased more than 65%, whereas the sCD14 levels in
the remaining 11 samples did not change (Fig.
7A). The endotoxin recovery was also
significantly higher in the six samples containing bioactive endotoxin
than in the 11 other samples (P < 0.01) (Fig. 7B).
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FIG. 6.
Effect of polymyxin B on biological activity of plasma.
Monocytes from healthy volunteers were incubated in a mixture with 50%
postoperative plasma with an endotoxin concentration above 0.20 EU/ml
in the presence and absence of polymyxin B (5 µg/ml). (A) Six out of
17 plasma samples showed a significant suppression of TNF- release
by polymyxin B. (B) Eleven out of 17 plasma samples showed almost no
change of TNF- release by polymyxin B. The TNF- level of the
supernatant is given on the y axis. Incubation time in hours
is depicted on the x axis.
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|
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FIG. 7.
Loss of sCD14 and ENC in plasma from six patients with
biologically active endotoxin and 11 patients without biologically
active endotoxin. (A) The postoperative sCD14 plasma content is given
on the y axis as a percentage (postoperative
sCD14/preoperative sCD14 × 100). (B) ENC is shown on the
y axis as the recovery of LPS exogenously added to the
plasma samples.
|
|
| |
DISCUSSION |
Although the presence of endotoxin in the systemic circulation has
been extensively studied in a variety of clinical settings, there is no
agreement on the occurrence of endotoxemia due to surgical stress. Many
studies have reported significant endotoxemia in humans after trauma
(25), major abdominal surgery (5), and cardiac
surgery (32). However, other well-designed studies have
failed to detect endotoxemia after trauma (27, 34) or hemorrhagic shock (11). These conflicting results were all
obtained after making complex measurements of endotoxin content by the LAL test, and the debates over the development of gut-derived endotoxemia have generally been based on the LAL test. We, however, believe that it may be more relevant to focus on the biological activity of circulating endotoxin, which is related to clinical outcome. Recent major studies have corroborated the pathophysiological importance of gut-derived endotoxemia in experiments using
antiendotoxin agents, such as polymyxin B (51), a cationic
antibiotic that stoichiometrically neutralizes the lipid A moiety of
endotoxin, or BPI (50), an endogenous endotoxin-neutralizing
protein that reduces endotoxin translocation during experimental
hemorrhage in rats and improves clinical outcome. In humans, the
selective decontamination of the digestive tract has been demonstrated
to reduce perioperative endotoxemia and release of interleukin 6 in
cardiac patients (32). In the present study, we assessed the
biological activity of the translocated endotoxin after major elective surgery.
Our results demonstrated the presence of significant endotoxemia during
major abdominal surgery, which is related to a loss of plasma ENC, as
described previously (4). Preoperative patient plasma
neutralized almost all exogenously added endotoxin, whereas postoperative plasma did not have enough capacity to neutralize the
same quantity of endotoxin, resulting in postoperative loss of ENC.
This study demonstrated reduced sCD14 plasma levels in the very early
postoperative stage, a finding similar to that of Kruger et al., who
observed decreased sCD14 concentrations immediately after multiple
trauma (28). Another new finding was a strong correlation
between sCD14 levels and ENC as determined by the LAL test. High sCD14
levels were associated with high ENC. The addition of MEM18, a
neutralizing anti-CD14 antibody (2), significantly
diminished the ENC of preoperative plasma samples. The effect on
postoperative plasma was less pronounced and not significant. One
explanation for this observation may be the presence of endogenous
endotoxin in postoperative plasma, as detected by the conventional LAL
test after heat inactivation. Pretreatment by heating is known to
destroy sCD14-endotoxin complexes, but ENC levels were determined
without any inactivation step. Thus, endogenous endotoxin may block
sCD14, resulting not only in loss of ENC but in a less pronounced
effect of anti-CD14 antibodies. These antibodies can only bind to
s/mCD14 before the addition of LPS (18). Preformed CD14-LPS
complexes are no longer accessible to the neutralizing action of MEM18,
and thus the ENC of postoperative plasma cannot be influenced by MEM18.
Plasma LBP levels were positively correlated with the ENC and sCD14
values. LBP is thought to facilitate the formation of LPS-s/mCD14
complexes, and it enhances LPS-induced cell activation (21, 43,
52). LBP may also catalyze sCD14-high-density
lipoprotein-dependent LPS neutralization (21, 49).
Therefore, the positive correlation between LBP and ENC reflects the
catalytic effect of LBP on sCD14-LPS binding and is compatible with
these LPS-neutralizing mechanisms. However, a more detailed study is
required to reveal the role of LBP itself in LPS neutralization.
Plasma BPI was not found to be correlated with ENC or LBP. BPI is a
potent LPS-neutralizing factor produced by polymorphonuclear leukocytes
(39) and has an antagonistic effect on LBP-related LPS-cell
interaction (10, 24). However, BPI did not seem to contribute to ENC, at least during the perioperative period, and BPI
release during that period seems to be modest. Therefore, significant
secretion of BPI later in the postoperative period may play a role as
an LPS-neutralizing mechanism.
The bioactivity of endotoxin in postsurgical plasma was determined by
measuring TNF- release from healthy monocytes after incubation with
plasma samples in the presence and absence of polymyxin B. In a
preliminary study, there was no procedural activation of monocytes
following steps taken to purify them from whole blood. The presence of
even very low concentrations of endotoxin (0.05 ng/ml) caused a
significant release of TNF- by monocytes that could be completely
abolished by the addition of polymyxin B. For the first time, the
biological activity of circulating endotoxin was demonstrated in our
study. Almost all of the 17 postoperative plasma samples with endotoxin
contents above 0.20 EU/ml stimulated TNF- secretion by healthy
monocytes, whereas no stimulation was observed in the stimulation assay
with preoperative plasma. The stimulatory activity of only 6 of the 17 postoperative plasma samples could be inhibited by the addition of
polymyxin B, indicating that biologically active endotoxin was present
in these six samples. In addition, these six samples had the lowest ENC
and the most pronounced decrease in sCD14 compared with preoperative
values. It should be noted that the absolute level of sCD14 was not
found to be associated with endotoxic bioactivity, despite the relative loss of sCD14 during the perioperative course. These six patients, however, were not distinguished by blood loss, duration of operation, or volume of infusion. Based on these preliminary results obtained in 6 of the 17 patients, we hypothesized that endotoxin present in the blood
after major surgical procedures may be bound to and consequently hidden
by sCD14. In our series of studies, we found that LPS bioactivity in
patients' plasma affected the clinical outcome assessed by Acute
Physiology and Chronic Health Evaluation (APACHE) II scores.
In conclusion, our findings suggest that sCD14 is an important
modulator of plasma ENC in the postoperative course, regulating the
endotoxin-dependent biological activity of plasma.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Surgery, The University of Tokyo, 3-28-6 Mejirodai Bunkyo-ku, Tokyo, 112-0086, Japan. Phone: 81-3-3943-1151. Fax: 81-3-3943-8530. E-mail: naki{at}bd.mbn.or.jp.
| |
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Clinical and Diagnostic Laboratory Immunology, November 1999, p. 844-850, Vol. 6, No. 6
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
