![[Feedback]](/icons/banner/feedbackACT.gif)
![[For Subscribers]](/icons/banner/subscriberACT.gif)
![[Archive]](/icons/banner/archiveACT.gif)
![[Search]](/icons/banner/searchACT.gif)
![[Contents]](/icons/banner/tocACT.gif)
Previous Article | Next Article 
Journal of Clinical Microbiology, April 1998, p. 1074-1080, Vol. 36, No. 4
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Immunoglobulin M Capture Assay for Serologic
Confirmation of Early Lyme Disease: Analysis of Immune Complexes with
Biotinylated Borrelia burgdorferi Sonicate Enhanced with
Flagellin Peptide Epitope
Michael
Brunner,1
Stanley
Stein,2
Paul D.
Mitchell,3 and
Leonard
H.
Sigal1,4,*
Department of Medicine1
Departments of Pediatrics and Molecular Genetics & Microbiology,4 University of Medicine and
Dentistry of New Jersey-Robert Wood Johnson Medical School, New
Brunswick, New Jersey;
Center for Advanced Biotechnology and
Medicine, University of Medicine and Dentistry of New Jersey, Robert
Wood Johnson Medical School and Rutgers University, Piscataway, New
Jersey2; and
Marshfield Laboratories,
Marshfield, Wisconsin3
Received 14 August 1997/Returned for modification 8 October
1997/Accepted 8 December 1997
 |
ABSTRACT |
We previously reported on the efficacy of the enzyme-linked
immunoglobulin M capture immune complex (IC) biotinylated antigen assay
(EMIBA) for the seroconfirmation of early Lyme disease and active
infection with Borrelia burgdorferi. In earlier work we identified non-cross-reacting epitopes of a number of B. burgdorferi proteins, including flagellin. We now report on an
improvement in the performance of EMIBA with the addition of a
biotinylated form of a synthetic non-cross-reacting immunodominant
flagellin peptide to the biotinylated B. burgdorferi B31
sonicate antigen source with the avidin-biotinylated peroxidase complex
detection system used in our recently developed indirect IgM-capture
immune complex-based assay (EMIBA). As in our previous studies, the
enzyme-linked immunosorbent assay (ELISA) reactivities of antibodies
liberated from circulating ICs (by EMIBA) were compared with those of
antibodies in unprocessed serum (antibodies found free in the serum,
thus as an IgM-capture ELISA, but not EMIBA, because the antibodies were not liberated from ICs), the sample usually used in standard ELISAs and Western blot assays. The addition of the flagellin epitope
enhanced the ELISA signal obtained with untreated sera from many Lyme
disease patients but not from healthy controls. In tests with both free
antibodies and ICs, with or without the addition of the flagellin
epitope to the sonicate, we found the most advantageous combination was
IC as the source of antibodies and sonicate plus the flagellin epitope
as the antigen. In a blinded study of sera obtained from patients with
early and later-phase Lyme disease, EMIBA with the enhanced antigenic
preparation compared favorably with other serologic assays, especially
for the confirmation of early disease.
| |
INTRODUCTION |
Lyme disease (LD) is a multisystem
inflammatory disorder (49) due to infection with the
spirochete Borrelia burgdorferi sensu lato, which is
transmitted by ticks in the Ixodes ricinus complex (5,
50). Soon after the tick bite the pathognomonic skin lesion
erythema migrans (EM) occurs in 50 to 75% of patients (49)
(and perhaps in as many as 90% of patients [20]), and this is often accompanied by nonspecific constitutional symptoms similar to those of a viral syndrome. If EM is present, the diagnosis of LD can be made without serologic confirmation. However, in the
absence of EM (or if the lesion is not identified properly), the
symptoms of early LD are nonspecific and objective signs of disease may
appear only later in the infection. Thus, in the absence of EM the
early and prompt diagnosis of early LD may be difficult to make on
purely clinical grounds. Due to the great public concern over LD, the
number of blood tests performed exceeds the number of confirmed cases
of LD by a factor of 100 (4). False-positive enzyme-linked
immunosorbent assay (ELISA) results are common, often resulting in an
incorrect diagnosis. It may take 6 to 8 weeks for seroconversion to
occur, so serologic confirmation of new infection may be delayed
(49). The current recommendation is to confirm all positive
or equivocal ELISA results by immunoblotting (8a) due to the
high frequency of false-positive ELISA results (i.e., a positive ELISA
result for a patient without LD). In our experience misinterpretation
of the results of Western blot analysis by practioners contributes to
the overdiagnosis of LD (45a).
Since early antibiotic treatment of LD is more effective in curing the
infection and preventing progression to later disease, our challenge
was to devise a serologic assay capable of detecting antibodies at the
earliest time after infection while severely limiting false-positive
responses. We have focused on detecting immunoglobulin M (IgM)
antibodies, which occur during the initial humoral immune response, and
in order to optimize the assay, we decided to incorporate the best of a
number of different assays. The IgM capture format was selected in
order to eliminate potential false-positive results from rheumatoid
factor (9, 29, 52) and competition that might otherwise
occur in a direct ELISA due to the relatively greater serum IgG
concentration (9, 52). Since previous studies have shown
that circulating specific anti-B. burgdorferi IgM antibodies
are frequently sequestered within antigen-antibody immune complexes
(ICs) (42-44), especially at an early stage of infection,
we chose to compare two sources of serum antibodies: IgM free in serum
versus IgM bound in ICs. In order to detect low levels of IgM we had
previously chosen biotinylated antigen, similar to Hansen et al.
(24), and an enzyme-avidin complex (8) to amplify
the signal while preserving a low background (7). This
combination of techniques, termed the enzyme-linked IgM capture IC
biotinylated antigen assay (EMIBA), was used to test a bank of serum
samples obtained from the Lyme Disease Center at the Robert Wood
Johnson Medical School. It was found to have better sensitivity (98%;
95% confidence interval [CI], 90 to 100%) than IgM ELISA (66%;
95% CI, 53 to 77%) or IgG ELISA (58%; 95% CI, 45 to 70%) and IgM
immunoblotting (58%; 95% CI, 45 to 70%) or IgG immunoblotting ELISA
(44%; 95% CI, 32 to 57%) and better specificity (96%; 95% CI, 87 to 99%) than IgM ELISA (76%; 95% CI, 64 to 86%) or IgG ELISA (87%;
95% CI, 76 to 93%) and IgM immunoblotting (84%; 95% CI, 72 to 91%)
or IgG immunoblotting (93%; 95% CI, 83 to 97%) (7).
Many ELISAs use a crude sonicate of B. burgdorferi to
interact with the antibodies in a patient's serum. One cause for
false-positive ELISA results is that serum antibodies to proteins found
on organisms other than B. burgdorferi may cross-react with
B. burgdorferi antigens (11, 32). Our laboratory
has previously identified linear epitopes of B. burgdorferi
proteins uniquely recognized by sera from patients with LD
(53), including one immunodominant flagellar peptide
(19, 41, 53, 54). The present study demonstrates the
signal-enhancing property of this flagellin epitope antigen in EMIBA
and provides support for our goal of replacing crude sonicates or whole
(even recombinant) proteins with a mixture of defined peptide epitopes
as antigens in a serodiagnostic assay.
| |
MATERIALS AND METHODS |
Growth and preparation of B. burgdorferi
sonicate.
High-passage B. burgdorferi B31
(22) from liquid nitrogen storage was grown at 32°C in
BSK-H medium made and filtered in our laboratory or purchased from
Sigma (St. Louis, Mo.) (3, 39) and supplemented with 6%
normal rabbit serum, grown in T flasks (Corning, Corning, N.Y.), and
harvested after 5 days (late logarithmic phase). Typically, 250 ml
(usual spirochetal cell count of approximately 7 × 107 cells/ml) was harvested by centrifugation at 9,000 × g for 15 min. The cell pellet was washed three times with
cold phosphate-buffered saline (PBS; pH 7.2). The final pellet was
either stored at 
70°C for later use or resuspended in 2 ml of PBS
and sonicated (medium setting; Braun-Sonic 2000) for four pulses of
30 s each with 1 min between pulses. The protein content of the
sonicate was about 3 mg/ml, as determined by the binchoninic acid (BCA)
protein assay (Pierce, Rockford, Ill.).
Flagellin peptide synthesis and conjugation to albumin.
Synthesis and purification (53) of the non-cross-reacting
flagellin epitope sequence VQEGVQQEGAQQP (positions F211 to F223, where F denotes the amino acid residue in flagellin) and conjugation of
the peptide to albumin have been described previously (54). For conjugation purposes, the epitope was synthesized with an additional cysteine residue at the carboxy terminus, followed by two
beta-alanine residues as a spacer and the epitope sequence. The
heterobifunctional reagent
m-maleimidobenzoyl-N-hydroxysuccinimide ester
(Pierce) was used to cross-link the cysteine thiol group in the peptide
to the side chain amino group in the lysine residues of bovine serum
albumin (BSA). Molar coupling ratios of between 13 and 22 (peptide:protein) were achieved, as determined by amino acid analysis
(54).
Biotinylation of antigens.
Different long-arm biotin
hydroxysuccinimide esters, including biotinamidocaproate
N-hydroxysuccinimide (NHS) ester (Sigma) and NHS-long-chain
(LC) biotin II (Pierce), were equally effective. One milliliter of a
3-mg/ml protein sonicate or epitope-BSA solution was adjusted to pH 9 by adding 0.1 volume of 0.5 M carbonate-bicarbonate buffer (pH 9)
immediately before biotinylation. To 1 ml of the pH-adjusted protein
sonicate, 7 µl of a 50-mg/ml biotin solution in diethylformamide was
added in a glass tube (16 by 100mm), covered, and slowly rotated for 1 to 2 h at room temperature, pipetting up and down every 15 min.
The reaction was stopped by adding 0.1 volume of 1 M Tris-HCl (pH 7.5).
At this point, the protease inhibitors phenylmethylsulfonyl fluoride
(0.5 mM), pepstatin A (0.7 µg/ml), and leupeptin (1 µg/ml) were
added to the reacted sonicate. Excess biotinylating reagent was removed
from both reactions by dialysis against three 2-liter changes of PBS
containing 0.02% sodium azide in the cold with a Slide-A-Lyzer
(Pierce) device with a 10,000-Da cutoff. The resulting biotinylated
product from the sonicate was assayed for protein by the BCA assay
(Pierce). Yields were typically at least 75%. Each biotinylated
reagent was diluted in buffer to a final concentration of 6 to 12 µg/ml. The biotinylated product from the sonicate retained full
activity in the ELISA for at least 6 months when it was stored at 4°C
(7).
Patient study population.
The sera used were well-defined
samples from Marshfield Laboratories (36), the University of
Minnesota and the Centers for Disease Control and Prevention (CDC)
(27a), and the Robert Wood Johnson Lyme Disease Center
clinic. Sera with the prefix MC (Marshfield Clinic) were obtained from
patients with culture-proven EM and were collected on the same day that
lesions were biopsied for culture. The skin biopsy procedure and
culture methods have been described previously (34, 36).
Samples designated 1 (EM and arthralgias), 2 (Lyme carditis), 3 (EM), 4 (Lyme arthritis), 5 (EM), and 6 (viral syndrome following tick bite)
were from patients evaluated at the Lyme Disease Center at the Robert
Wood Johnson Medical School and were adjudged to have LD by one of the
authors (L.H.S.). All were IgM ELISA positive and fulfilled CDC IgM
immunoblotting criteria (16) on evaluation with the MarDx
(Carlsbad, Calif.) isotype-specific ELISA and immunoblotting kits
(following the manufacturer's instructions) at the Lyme Disease
Diagnostic Laboratory of the University Diagnostic Laboratories of
Robert Wood Johnson Medical School. Samples 2, 4, and 5 were also IgG
ELISA and IgG immunoblotting positive by the CDC criteria, and sample 3 was IgG ELISA positive but immunoblotting negative (IgG reactivity with
58-, 45-, 41-, and 39-kDa bands). The patient from whom sample 7 was
obtained was not thought to have evidence of active Lyme disease solely
on the basis of a clinical evaluation by one of the authors (L.H.S.)
and was IgG and IgM negative by isotype-specific ELISA and
immunoblotting.
Sera designated MC were from patients with EM either single or multiple
lesions seen at the Marshfield Clinic. Sera designated MCC were
negative control samples obtained at the Marshfield Clinic from
individuals without a history of current or past infection with
B. burgdorferi. Other negative control samples were obtained at the Lyme Disease Center from patients in whom LD was not suspected on the basis of clinical and laboratory evaluation by one of the authors (L.H.S.). Serum samples 807 (EM), 930 (EM), 948 (negative control), 949 (negative control), and 952 (Lyme arthritis) were obtained from CDC as part of a panel of samples provided and used in
previous studies (7); the histories of the patients from whom these samples were obtained were unblinded only after completion of the studies described here. Samples 948 and 949 were negative by
isotype-specific ELISA and immunoblotting. All the other samples from
CDC used in this study were IgM ELISA and immunoblotting positive;
serum sample 807 was also IgG ELISA and immunoblotting positive, and
sample 930 fulfilled the IgG immunoblotting criteria, although it was
negative by ELISA.
Serum collection.
Blood was drawn, clotted at room
temperature, and centrifuged in a Sorvall RC5C, HS-4, rotor at 769 × g for 10 min. Clear serum was drawn off with a pipette.
After analysis the serum was stored at 70°C until it was needed for
further testing. Freezing-thawing slightly decreased the reactivities
of some samples, but it did not reduce the results for any positive
samples into the negative range (7).
IC purification.
The polyethylene glycol (PEG) method for IC
precipitation was used (7). Briefly, 100 µl of serum was
precipitated with an equal volume of a 7% PEG (average molecular
weight, 8,000; Sigma) solution in 0.1 M sodium borate-0.075 M sodium
chloride buffer (pH 8.4) in the cold. The microcentrifuge tube was
vortexed, kept at 4°C for 2 to 16 h, and then centrifuged at
8,320 × g for 15 min in the cold. The supernatant was
carefully removed with a Pasteur pipette, and the pellet was
resuspended and washed twice with 200 µl of 3.5% PEG in 0.1 M sodium
borate-0.075 M sodium chloride buffer (pH 8.4). The pellet was
resuspended in its original volume with 0.1 M sodium borate buffer (pH
10.2) and was kept at 4°C until it was used.
M-capture ELISA.
The M-capture ELISA was performed as
described previously (7). Briefly, Immulon 4 microtiter
plates (Dynatek, Chantilly, Va.) were coated with 100 µl of 10 µg
of affinity-purified anti-human IgM (mu-chain specific) antibody
(Rockland, Gilbertsville, Pa.; Kirkegaard & Perry Laboratories, Inc.,
Gaithersburg, Md.) per ml at 100 µl/well in 0.04 M
carbonate-bicarbonate buffer (pH 9.6), slowly rotated for 2 h at
room temperature, and kept at 4°C overnight. The plates were washed
three times in a plate washer (ELP35; Biotek, Winooski, Vt.) with 10 mM
PBS (the NaCl concentration was 0.15 M) containing 0.1% BSA (Sigma)
(PBS-B), each well was blocked with 300 µl of PBS-B containing 5%
nonfat dry milk (Bio-Rad) with 0.02% sodium azide for 1 to 2 h at
37°C, and the plates were washed twice with PBS-B. Serum samples (100 µl) were diluted in blocking buffer (containing azide) (1:10 for IC
and 1:100 for free antibody), and added in duplicate. The plate was
slowly rotated overnight at room temperature to optimize IgM capture.
EMIBA was developed so the same positive controls in each run gave an
optical density (OD) of approximately 1.0, negative controls gave an OD
of less than 0.1, and bare well controls gave an OD of 0.05 or less
when read at dual wavelengths (450 and 630 nm; signal at 450 nm, with
the background at 630 nm subtracted) on an ELISA plate reader
(Bio-Tek). The net OD at 450 nm (OD450) was calculated as
follows: net OD450 = (OD450 of sample OD630 of sample) (OD450 of blank well OD630 of blank well). The optimal amounts of antigenic
preparations were determined for each batch made (4 to 12 µg/ml), and
each batch was standardized with the preceding preparation by using the
same positive and negative serum panels. The optimal dilution for
dissociated ICs was 1/10, and that for serum was 1/100; there was no
increase in reactivity when sera were run at a dilution of 1/10.
The reagent (100 µl), diluted in blocking buffer without sodium
azide, was added to each well, and the plate was rotated at 300 rpm on
a Titer Plate Shaker (Lab-Line, Melrose Park, Ill.) at room temperature
for 1 h. During this time, the avidin-biotinylated peroxidase
complex (ABC; Vector Laboratories, Burlingame, Calif.) was formed by
adding 1 drop (50 µl) of reagent A (avidin DH) and 1 drop of reagent
B (biotinylated peroxidase) to 5 ml of PBS-B (the NaCl concentration
was increased to 0.5 M) containing 0.1% Tween 20 (PBS-BT), and the
complex was vortexed and kept at room temperature for at least 30 min
before use. After complex formation, 7 ml of PBS-BT was added to the
ABC reagent as described above. The plate was washed four times with
PBS-B, and 100 µl of the diluted ABC reagent was added to each well.
The plate was placed on an orbital shaker and shaken at 300 to 400 rpm
for 30 min at room temperature. The plate was washed four times with
PBS-B (on the Bio-Tek plate washer) followed by two more manual washes
with PBS-T (no BSA) for 5 min each time with a multichannel pipette (Brinkmann Transferpette) on a rotator. During the last wash, the
two-component 3,3',5,5'-tetramethylbenzidine substrate solution (Kirkegaard & Perry Laboratories, Inc.) was prepared at room
temperature. Substrate (100 µl/well) was added with a repeater
pipette (Eppendorf Plus/8), the plate was rotated for 10 min, and the
reaction was stopped by adding 1 M phosphoric acid (100 µl/well). The
plate was then rotated for 2 more min to homogenize the yellow color. The wells in which a reaction occurred were then read on an ELISA plate
reader (Biotek) set for dual wavelengths (450 and 630 nm). Blank and
antigen control wells always had readings of less than 0.05 OD units.
Sera from 10 subjects in New Jersey who did not have a clinical
diagnosis of LD and who were seronegative by both Western blotting and
a commercial ELISA (MarDx) were used as negative control samples on
each experimental plate; the number of negative controls was in keeping
with previous studies (42). The index value was calculated
as follows: index value = (mean net OD450 of
sample)/(mean net OD450 plus 3 standard deviations for 10 negative controls). An index value above 1.0 was considered positive,
whereas an index value of 0.8 to 0.99 (approximately 2 to 3 standard
deviations above the mean) was considered equivocal and an index value
below 0.8 was considered negative. Each sample was tested in duplicate, with the precision typically being within a 3% average deviation.
Immunoserologic methods.
The procedures for IgM indirect
fluorescent-antibody assay (IFA) and IgM immunoblotting have been
described previously (35). The polyvalent enzyme immunoassay
(EIA) and a recombinant p39-based IgM EIA (dot blot) were supplied in
kit form (General Biometrics, San Diego, Calif.) and were used
according to the manufacturer's instructions.
| |
RESULTS |
Influence of the addition of the non-cross-reacting flagellin
epitope on serologic reactivity with the standard antigen preparation,
the borrelial sonicate.
We previously reported on EMIBA, which
uses an IgM-capture format with IgM derived from purified, disrupted
ICs with a biotinylated sonicate of B. burgdorferi as the
antigen and ABC as the detection system (7). The addition of
a biotinylated, albumin-conjugated immunodominant flagellin epitope to
the standard antigen preparation was studied. Initial studies used
serum rather than IC-derived antibodies.
Sample 7, representative of more than 50 samples from subjects without
LD from among our non-LD control samples and similar negative control
samples from other laboratories, produced a low OD, i.e., below the
negative cutoff, in our assay with the sonicate alone, the flagellin
epitope alone, or the combination of the flagellin epitope and the
sonicate (Fig. 1).
View larger version (33K):
[in this window]
[in a new window]
|
FIG. 1.
Influence of synthetic flagellin epitope (unprocessed
serum). Serum samples from patients were assayed for LD (Lyme specific
IgM antibodies) by M-capture ELISA. Either the biotinylated whole-cell
sonicate (Bb-bio) alone (a), the biotinylated whole-cell sonicate
(Bb-bio) plus biotinylated flagellin synthetic epitope-BSA conjugate
(Fla-bio) (b), or the biotinylated flagellin synthetic epitope-BSA
conjugate (Fla-bio) alone (c) was used as the antigen source. Results
are expressed as net mean OD450, as defined in Materials
and Methods. The sets of bars represent data for samples from patients
7, 1 (22 May 1997), 1 (23 May 1997), 2 to 5 and 95-11891 from left to
right, respectively.
|
|
Samples 1 and 2, serum samples from two patients with LD, showed
moderate responses in tests with the sonicate alone; the OD in the same
assay with either the flagellin epitope alone or the combination of the
flagellin epitope and the sonicate was much higher. This phenomenon was
reproducible among assays done on different days, as shown with two
assays with sample 1 done on 22 and 23 May 1997 (Fig. 1).
Serum sample 3, from a patient with LD, gave a strong signal with the
flagellin epitope antigen or the sonicate alone, but there was no
appreciable enhancement in response with the combination of sonicate
and the flagellin epitope compared to that with the sonicate alone.
Serum samples 4 and 5, from patients with LD, were strongly positive
when the sonicate was used, but there was little reactivity when the
flagellin epitope alone was used and no enhancement in reactivity when
the combination of sonicate and flagellin epitope was used compared
with the reactivity obtained with the sonicate alone. Serum sample
95-11891, from a patient with LD, was negative in the standard assay
with only the sonicate, but it was positive with the flagellin epitope
alone or the combination of the flagellin epitope with the sonicate
(Fig. 1). Thus, for sera from some but not all patients with LD, the
addition of the flagellin epitope enhanced the OD reading. For one
sample described here, the addition of the flagellin epitope increased
the OD sufficiently to place a serum sample from a patient with LD
within the seropositive range. Seroconfirmation of LD in such a patient
was possible only with the addition of the flagellin epitope. In no
cases did the addition of the flagellin epitope place a serum sample
from a subject without LD into the seropositive range.
Comparison of IC-derived IgM with serum as source of antibodies
with and without the addition of the flagellin epitope.
Our
previous work demonstrated that IC is superior to free serum antibodies
in EMIBA (7). Thus, we compared the use of IC-derived
antibodies with the use of free serum antibodies in assays with the
standard borrelial sonicate or with the sonicate and the flagellin
epitope. An example of the results obtained in such a comparison study
is presented in Fig. 2; each assay included at least 10 control serum samples from subjects without LD
(data not shown in Fig. 2); these samples were used to calculate a
normalization index value. The results obtained with the first four
samples from patients with LD, samples 807, MC-2, WS, and MC-10
(confirmed to be positive by three different laboratories), indicate
that the addition of the synthetic flagellin epitope enhanced the
results obtained with both free antibody and IC-derived antibody for
sample MC-10. The absolute enhancement of the free antibody result was
much less than that seen in the assay with IC as the source of
antibodies. For sample 930 no enhancement of the result obtained with
free antibody or IC-derived antibody was found. For control samples
from subjects without LD (samples 948, 949 and 952), all four assay
methods gave negative results, with no enhancement achieved by the
addition of the flagellin epitope.
View larger version (35K):
[in this window]
[in a new window]
|
FIG. 2.
Influence of synthetic epitope flagellin antigen on free
and IC-derived L antibodies to B. burgdorferi. Serum samples
from patients containing IC-derived antibody (precipitated with PEG and
resuspended in PEG) assayed with biotinylated whole-cell sonicate
(Bb-bio) alone (a), serum samples containing IC-derived antibody
assayed with biotinylated whole-cell sonicate (Bb-bio) plus
biotinylated flagellin synthetic epitope-BSA conjugate (Fla-bio) (b),
serum samples containing free (untreated) antibody assayed with
biotinylated whole-cell sonicate (Bb-bio) alone (c), and serum samples
containing free (untreated) antibody assayed with biotinylated
whole-cell sonicate (Bb-bio) plus biotinylated flagellin synthetic
epitope-BSA conjugate (Fla-bio) (d) as the antigen source were used to
detect LD-specific IgM antibodies in M-capture ELISA. Results are
expressed as an index value, as defined in Materials and Methods.
|
|
The results presented in Fig. 1 and 2 illustrate a variety of serologic
results presumably due to different LD antibody repertoires, but in
general, sera from LD patients (with or without flagellin epitope
enhancement) had a higher OD result when IC was the source of
antibodies, consistent with our previous results (7).
Neither the use of IC-derived antibodies nor the addition of the
synthetic flagellin epitope created false-positive results for sera
from subjects without LD.
Blinded study of serum samples with flagellin epitope-enhanced
borrelial sonicate as the antigen in EMIBA.
ICs were prepared from
the sera in the Marshfield Clinic collection of well-characterized
samples from patients from whose EM lesions B. burgdorferi
had been cultured (36). Unprocessed serum (free antibodies)
and ICs were tested by EMIBA with either the sonicate or a combination
of the sonicate and flagellin epitope antigen (Fig.
3). Many of these samples had previously
produced inconsistent results in different LD-related immunoassays
(36), although the clinical diagnosis had been confirmed by
culture of the spirochete from biopsy specimens of EM lesions (Table
1). The samples were analyzed in a
blinded fashion, but the results are presented in Fig. 3 in three
groups: for patients with (i) multiple EM lesions (disseminated or
secondary lesions) or (ii) single lesions and (iii) for negative
control subjects.
View larger version (29K):
[in this window]
[in a new window]
|
FIG. 3.
M-capture ELISA used to detect LD-specific IgM
antibodies in patients with multiple lesions, patients with single
lesions, and negative control patients. Serum samples from patients
containing IC-derived antibody (precipitated with PEG and resuspended
in PEG) assayed with biotinylated whole-cell sonicate (Bb-bio) alone
(a), serum samples containing IC assayed with biotinylated whole-cell
sonicate (Bb-bio) plus biotinylated flagellin synthetic epitope-BSA
conjugate (Fla-bio) (b), and free (untreated) serum samples containing
free (untreated) antibody assayed with biotinylated whole-cell sonicate
(Bb-bio) alone (c) as the antigen source were tested. Results are
expressed as an index value, as defined in Materials and Methods.
|
|
View this table:
[in this window]
[in a new window]
|
TABLE 1.
Comparison of M-capture ELISA results with other Lyme
test results of other assays for LD for patient samples from patients
with primary and secondary LDa
|
|
All ICs from patients with multiple lesions gave an index above 1.2 (above the cutoff value of 1.0) when they were tested with the combined
sonicate and flagellin epitope (Figure 3). For seven of these nine
samples, the flagellin epitope enhanced the reactivity to a level
greater than that achieved with the sonicate alone. With the exception
of sample MC-23, all ICs from this group of samples from patients with
multiple lesions tested in the positive range with the sonicate only.
Sample MC-23 gave negative results in repeated assays without the
addition of the flagellin peptide epitope. Both sample MC-23 and sample
MC-41 would have had false-negative results if they had been tested
with serum (free antibody) as the source of antibody with the standard
antigen preparation (the sonicate) rather than with IC-derived IgM and
the enhanced antigenic preparation. Sample MC-41 had previously tested
negative by an IgM immunoblotting assay and equivocal by an IgM dot
blot assay (Table 1).
Among the group of samples from patients with single lesions, 8 of 11 samples (all but samples MC-11, MC-24, and MC-8) had values above the
cutoff index value of 1 when IC-derived IgM was tested with the
combined antigen preparation (Fig. 3). Testing for IC-derived IgM with
only the sonicate would have given false-negative results for two of
the positive samples (samples MC-17 and MC-25). In the IgM
immunofluorescence assays done previously, the result for sample MC-4
was negative, while the results for samples MC-35 and MC-17 were
contradictory (Table 1).
Of the three negative samples in this group, sample MC-11 gave an
equivocal result, whereas samples MC-24 and MC-8 were negative when
they were tested for either free antibody or IC-derived IgM. Sample
MC-8 was negative by all other IgM immunoassays done previously, whereas samples MC-11 and MC-24 gave contradictory results (Table 1).
All nine control serum samples from subjects without LD were negative
in tests with free antibody or IC with either sonicate or a combination
of sonicate and the flagellin epitope antigen; no enhancement due to
the addition of the flagellin epitope was noted (Fig. 3).
In summary, all samples from subjects without LD tested negative by
EMIBA, whether for IC-derived IgM or free IgM, with or without the
addition of the flagellin epitope. For patients with multiple EM
lesions, all samples tested positive in tests with IC when the sonicate
and flagellin epitope antigen were used, even though other IgM assays
were nonconfirmatory for the diagnosis of LD (Table 1). For the samples
from patients with single EM lesions, 8 of 11 were positive by our
format with IC-derived IgM and the combination of antigens. By
comparison, the previously reported immunofluorescence assay for IgM
scored only 6 of 11 samples as positive, while the other assays were
less likely to predict the clinical status of the patient (Table 1).
| |
DISCUSSION |
Our goal was to design an immunoassay useful for confirming the
clinical diagnosis of LD at the earliest possible time; consequently, we developed EMIBA, an indirect IgM-capture IgM assay. The advantages of this format have been described previously (7). By
measuring 1 dilution (with a saturating anti-IgM concentration coating
the plates), the M-capture assay gives a good approximation of the antibody load for the specific IgM antibody for the disease, accurately correlating the antibody load with the clinical condition
(45). The use of biotinylated antigen (24) with
an ABC detection system increases sensitivity and obviates the use (and
production) of anti-B. burgdorferi secondary labeled
antibodies (16) or F(ab)2 fragments (6,
12). We found that by using IC-derived IgM we could detect
antibodies in the sera of patients with LD who were negative by
standard assays (Table 1) while maintaining negative results with
control samples (7). These findings are confirmed in the
current studies: EMIBA with IC-derived IgM can detect levels of
antibodies well within the positive range for many samples determined
to be false negative or equivocal by standard assays (e.g., Fig. 3,
samples MC-41 and MC-48) or increase the value of the result for
positive samples (e.g., Fig. 3, samples MC-35 and MC-55) without a
parallel increase in the OD for control samples, thereby giving a more
sensitive assay.
Enhancement of the standard antigenic preparation, a borrelial
sonicate, with the addition of an albumin-conjugated flagellin peptide
epitope in some cases boosted the OD result without falsely increasing
the signal derived from true-negative samples. This enhancement might
be clinically important, as with serum samples MC-23 and MC-17 (Fig.
3), in which it corrected an otherwise false-negative result.
The flagellin peptide epitope used here was chosen on the basis of
previous studies demonstrating that it was not bound by sera from
patients without LD (14, 15). It did not decrease the
specificity of the EMIBA, as demonstrated by the absence of enhancement
of the values for true-negative samples. The current studies confirm
that sera from subjects without LD do not bind to this epitope which is
of great importance since flagellin contains many epitopes that are
cross-reactive and flagellin-based assays can yield false-positive
results in seroconfirmatory tests for LD (1, 31, 51).
Although purified flagellin has been useful for the seroconfirmation of
Lyme neuroborreliosis (25), attempts to improve the
sensitivity of ELISA with flagellin-enriched preparations or purified
flagellin antigens have given variable results (10), and
false-positive results have been obtained in indirect ELISAs (21); ELISA with recombinant flagellin is also prone to
cross-reactivity (33). The flagellin-enriched antigen was as
sensitive as the sonicate in one study (21) and more
sensitive than the whole sonicate in another (10). Some
studies found purified flagellin to be superior (26, 27) and
to increase the sensitivity of detection of IgG in patients with EM or
neuroborreliosis (although there was no such improvement in patients
with acrodermatitis chronica atrophicans [28]); of
relevance to our design of an assay for early LD, there was no
significant difference in IgM titers for any of the patient groups, nor
was the sensitivity of detection of IgM (or IgG) in cerebrospinal fluid
from patients with neuroborreliosis affected (28).
Potentially even greater specificity and sensitivity may be achieved by
replacing the sonicate (or recombinant proteins) entirely with a
mixture of peptides serving as the antigen source (54),
e.g., synthetic peptide epitopes of p39 (30, 46, 47), p23
(OspC) (38), and perhaps p25 (2), in addition to
our p41 (flagellin) epitope, for a better seroconfirmatory test for
early LD.
Some studies have shown the superiority of immunoblotting over ELISA
for the seroconfirmation of LD (2, 16, 17, 40); of note,
Aguero-Rosenfeld et al. (2) used a polyvalent rather than
IgM-specific secondary antibody which may contribute to the performance
of immunoblotting. Immunoblotting is still not standardized (48,
51), and discussion of the appropriate criteria for a standard
immunoblot assay continues, with this discussion being fueled by recent
work with receptor operating characteristics analysis for early LD
(48). Immunoblotting is labor- and cost-intensive and
relatively cumbersome (compared to ELISA), and interpretation of the
results is subjective (16, 17, 37, 55).
Table 1 demonstrates that this enhancement of EMIBA yields results that
correlate better with the clinical condition (patients with EM and
culture positive culture result) than other serologic assays, including
Western blotting, or a recombinant p39 dot blot (7, 35). In
comparison to other seroconfirmatory assays, the improved EMIBA more
accurately demonstrated true positivity for a group of patients with
primary symptoms (single lesions), which represent early disease (Fig.
3) (Table 1). Current serologic assays are incapable of confirming the
diagnosis of LD for a large proportion of patients with early disease,
suggesting to us that a new seroconfirmatory assay rather than a
modification of current criteria may be the most appropriate next step
in test design and interpretation. EMIBA may be suitable for
seroconfirmation of LD in patients with somewhat later stages of LD, as
evidenced by the results for patients with multiple lesions (Table 1). Indeed, persistence of IgM seroreactivity (1, 13, 24) has been found in patients with LD, and IgM can be found for more than 1 year in patients who were apparently successfully treated for early LD
(18, 23). Thus, measurement of whole unprocessed serum (free
antibody in our terminology) for anti-B. burgdorferi IgM
reactivity by the standard serologic assays with which we compared that
method with EMIBA can produce positive results; these positive results
have no known clinical significance, i.e., they do not suggest active
infection (18, 23), although misinterpretation of serologic
reactivity, especially IgM seroreactivity, which is synonymous with
active disease, by referring clinicians is common in our experience
(45a, 45b).
EMIBA measures ICs rather than free antibody, as described previously.
It substantially reduces the rate of false-positive results, it better
correlates with the patient's clinical status than standard ELISA or
immunoblotting, and it is capable of seroconfirmation of LD before
ELISA or immunoblotting (7). With the addition of the
flagellin epitope, we think the principle of using preselected epitopes
rather than crude sonicate or recombinant proteins as an antigenic
source was satisfactorily demonstrated. Current studies in our
laboratory are expanding on the current work, and we are using other
epitopes in the development of better serologic assays (14, 15,
53) and other relevant control groups, including sera from
patients other infectious diseases (syphilis, Epstein-Barr virus
infection, and other borrelia infections) and noninfectious diseases
(lupus and rheumatoid arthritis). The goal of these studies is to
develop a standardized antigenic preparation for serologic assays whose
results are corroborated in comparison with the results for these other
diseases used as controls.
| |
ACKNOWLEDGMENTS |
We thank Russell Johnson of the University of Minnesota for
sending well-characterized blinded samples for evaluation and William
Schrier and Barbara Johnson of CDC for serum samples.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 1 Robert Wood
Johnson Place MEB 484, New Brunswick, NJ 08903-0019. Phone: (732)
235-7704. Fax: (732) 235-7238. E-mail: sigallh{at}umdnj.edu.
| |
REFERENCES |
| 1.
|
Aguero-Rosenfeld, M.,
J. Nowakowski,
S. Bittker,
D. Cooper,
R. B. Nadelman, and G. P. Wormser.
1996.
Evolution of the serologic response to Borrelia burgdorferi in treated patients with culture-confirmed erythema migrans.
J. Clin. Microbiol.
34:1-9[Abstract].
|
| 2.
|
Aguero-Rosenfeld, M.,
J. Nowakowski,
D. F. McKenna,
C. A. Carbonaro, and G. P. Wormser.
1993.
Serodiagnosis in early Lyme disease.
J. Clin. Microbiol.
31:3090-3095[Abstract/Free Full Text].
|
| 3.
|
Barbour, A.
1984.
Isolation and cultivation of Lyme disease spirochetes.
Yale J. Biol. Med.
57:521-525[Medline].
|
| 4.
|
Barbour, A. G., and D. Fish.
1993.
The biological and social phenomena of Lyme disease.
Science
260:1610-1616[Abstract/Free Full Text].
|
| 5.
|
Benach, J.,
E. M. Bosler,
J. P. Hanrahan,
J. L. Coleman,
G. S. Habicht,
T. F. Bast,
D. J. Cameron,
J. L. Ziegler,
A. G. Barbour,
W. Burgdorfer,
R. Edelman, and R. A. Kaslow.
1983.
Spirochetes isolated from the blood of two patients with Lyme disease.
N. Engl. J. Med.
308:740-742[Abstract].
|
| 6.
|
Berardi, V.,
K. E. Weeks, and A. C. Steere.
1988.
Serodiagnosis of early Lyme disease: analysis of IgM and IgG antibody responses by using an antibody-capture enzyme immunoassay.
J. Infect. Dis.
158:754-760[Medline].
|
| 7.
|
Brunner, M.,
S. Stein, and L. H. Sigal.
1997.
Enzyme-linked, IgM capture, immune complex, biotinylated antigen assay (EMIBA): a new serologic assay for early Lyme disease.
Arthritis Rheum.
40:S142.
|
| 8.
|
Brunner, M.,
C. Moriera-Filho, and S. S. Wachtel.
1984.
On the secretion of H-Y antigen.
Cell
37:615-619[Medline].
|
| 8a.
|
Centers for Disease Control and Prevention.
1995.
Recommendations for test performance and interpretation from the Second National Conference on Serologic Diagnosis of Lyme Disease.
Morbid. Mortal. Weekly Rep.
44:590-591[Medline].
|
| 9.
|
Cerny, E. H.,
C. E. Farshy,
E. F. Hunter, and S. A. Larsen.
1985.
Rheumatoid factor in syphilis.
J. Clin. Microbiol.
22:89-94[Abstract/Free Full Text].
|
| 10.
|
Coleman, J., and J. Benach.
1987.
Isolation of antigenic components from the Lyme disease spirochete: their role in early diagnosis.
J. Infect. Dis.
155:756-765[Medline].
|
| 11.
|
Coleman, J. L., and J. L. Benach.
1992.
Characterization of antigenic determinants of Borrelia burgdorferi shared by other bacteria.
J. Infect. Dis.
165:658-666[Medline].
|
| 12.
|
Coyle, P.,
Z. Deng,
S. E. Schutzer,
A. L. Belman,
J. Benach,
L. B. Krupp, and B. Luft.
1993.
Detection of Borrelia burgdorferi antigens in cerebrospinal fluid.
Neurology
43:1093-1097[Abstract/Free Full Text].
|
| 13.
|
Craft, J. E.,
D. K. Fischer,
G. T. Shimamoto, and A. C. Steere.
1986.
Antigens of Borrelia burgdorferi recognized during Lyme disease.
J. Clin. Invest.
78:934-939.
|
| 14.
|
Dai, Z.,
H. Lackland,
S. Stein,
Q. Li,
R. Radziewicz,
S. Williams, and L. Sigal.
1993.
Molecular mimicry in Lyme disease: monoclonal antibody H9724 to Borrelia burgdorferi flagellin specifically detects chaperonin-HSP60.
Biochim. Biophys. Acta
1181:97-100[Medline].
|
| 15.
|
Dai, Z. Z.
1993.
Definition of the epitope on the 41-kDa flagellin of Borrelia burgdorferi for a monoclonal antibody H9724 and identification of a H9724-reactive protein from calf adrenal gland. Ph.D thesis.
Rutgers University, Piscatawy, N.J.
|
| 16.
|
Dressler, F.,
J. A. Whalen,
B. N. Reinhardt, and A. C. Steere.
1993.
Western blotting in the serodiagnosis of Lyme disease.
J. Infect. Dis.
167:392-400[Medline].
|
| 17.
|
Engstrom, S.,
E. Shoop, and R. C. Johnson.
1995.
Immunoblot interpretation criteria for serodiagnosis of early Lyme disease.
J. Clin. Microbiol.
33:419-427[Abstract].
|
| 18.
|
Feder, H. M.,
M. A. Gerber,
S. W. Luger, and S. W. Ryan.
1992.
Persistence of serum antibodies to Borrelia burgdorferi in patients treated for Lyme disease.
Clin. Infect. Dis.
15:788-793[Medline].
|
| 19.
|
Fikrig, E.,
E. D. Huguenel,
R. Berland,
D. W. Rahn,
J. A. Hardin, and R. A. Flavell.
1992.
Serologic diagnosis of Lyme disease using recombinant outer surface proteins A and B and flagellin.
J. Infect. Dis.
165:1127-1132[Medline].
|
| 20.
|
Gerber, M. A.,
E. D. Shapiro,
G. S. Burke,
V. J. Parcells, and G. L. Bell.
1996.
Lyme disease in children in southeastern Connecticut.
N. Engl. J. Med.
335:1270-1274[Abstract/Free Full Text].
|
| 21.
|
Grodzicki, R., and A. C. Steere.
1988.
Comparison of immunoblotting and indirect enzyme-linked immunosorbent assay using different antigen preparations for diagnosing early Lyme disease.
J. Infect. Dis.
157:790-797[Medline].
|
| 22.
|
Guner, E.
1994.
Retention of B. burgdorferi pathogenicity and infectivity after multiple passages in a co-culture system.
Experientia
50:54-59[Medline].
|
| 23.
|
Hammers-Berggren, S.,
A. M. Lebech,
M. Karlsson,
B. Svenungsson,
K. Hansen, and G. Stiernstedt.
1994.
Serological follow-up after treatment of patients with erythema migrans and neuroborreliosis.
J. Clin. Microbiol.
32:1519-1532[Abstract/Free Full Text].
|
| 24.
|
Hansen, K.,
K. Pii, and A.-M. Lebech.
1991.
Improved immunoglobulin M serodiagnosis in Lyme borreliosis by using a mu-capture enzyme-linked immunosorbent assay with biotinylated Borrelia burgdorferi flagella.
J. Clin. Microbiol.
29:166-173[Abstract/Free Full Text].
|
| 25.
|
Hansen, K., and A. M. Lebech.
1991.
Lyme neuroborreliosis: a new sensitive diagnostic assay for intrathecal synthesis of Borrelia burgdorferi specific immunoglobulin G, A, and M.
Ann. Neurol.
30:197-205[Medline].
|
| 26.
|
Hansen, K.,
P. Hindersson, and N. S. Pedersen.
1988.
Measurement of antibodies to the Borrelia burgdorferi flagellum improves serodiagnosis in Lyme disease.
J. Clin. Microbiol.
26:338-346[Abstract/Free Full Text].
|
| 27.
|
Hansen, K., and E. Asbrink.
1989.
Serodiagnosis of erythema migrans and acrodermatitis chronica atrophicans by the Borrelia burgdorferi flagellum enzyme-linked immunosorbent assay.
J. Clin. Microbiol.
27:545-551[Abstract/Free Full Text].
|
| 27a.
|
Johnson, B. J. B.,
K. E. Robbins,
R. E. Bailey,
B.-L. Cao,
S. L. Sviat,
R. B. Craven,
L. W. Mayer, and D. T. Dennis.
1996.
Serodiagnosis of Lyme disease: accuracy of a two-step approach using a flagella-based ELISA and immunoblotting.
J. Infect. Dis.
174:346-353[Medline].
|
| 28.
|
Karlsson, M.,
G. Stiernstedt,
M. Granstrom,
E. Asbrink, and B. Wretlind.
1990.
Comparison of flagellum and sonicate antigens for serological diagnosis of Lyme borreliosis.
Eur. J. Clin. Microbiol. Infect. Dis.
9:169-177[Medline].
|
| 29.
|
Lovece, S.,
R. Stern, and L. J. Kagen.
1991.
Effects of rheumatoid factor, antinuclear antibodies and plasma reagin on the serologic assay for Lyme disease.
J. Rheumatol.
18:1813-1818[Medline].
|
| 30.
|
Ma, B.,
B. Christen,
D. Leung, and C. Vigo-Pelfrey.
1992.
Serodiagnosis of Lyme borreliosis by Western immunoblot: reactivity of various significant antibodies against Borrelia burgdorferi.
J. Clin. Microbiol.
30:370-376[Abstract/Free Full Text].
|
| 31.
|
Magnarelli, L.,
J. G. F. Anderson, and R. C. Johnson.
1987.
Cross-reactivity in serological tests for Lyme disease and other spirochetal infections.
J. Infect. Dis.
156:183-188[Medline].
|
| 32.
|
Magnarelli, L.,
J. N. Miller,
J. F. Anderson, and G. R. Riviere.
1990.
Cross-reactivity of nonspecific treponemal antibody in serologic tests for Lyme disease.
J. Clin. Microbiol.
28:1276-1279[Abstract/Free Full Text].
|
| 33.
|
Magnarelli, L.,
E. Fikrig,
S. J. Padula,
J. F. Anderson, and R. A. Flavell.
1996.
Use of recombinant antigens of Borrelia burgdorferi in serologic tests for diagnosis of Lyme borreliosis.
J. Clin. Microbiol.
34:237-240[Abstract].
|
| 34.
|
Melski, J.,
K. D. Reed,
P. D. Mitchell, and D. G. D. Barth.
1993.
Primary and secondary erythema migrans in central Wisconsin.
Arch. Dermatol.
129:709-716[Abstract].
|
| 35.
|
Mitchell, P.,
K. D. Reed,
T. L. Aspeslet,
M. F. Vandermause, and J. W. Melski.
1994.
Comparison of four immunoserologic assays for detection of antibodies to Borrelia burgdorferi in patients with culture-positive erythema migrans.
J. Clin. Microbiol.
32:1958-1962[Abstract/Free Full Text].
|
| 36.
|
Mitchell, P.,
K. D. Reed,
M. F. Vandermause, and J. W. Melski.
1993.
Isolation of Borrelia burgdorferi from skin biopsy specimens of patients with erythema migrans.
Am. J. Clin. Pathol.
99:104-107[Medline].
|
| 37.
|
Pachner, A. R., and N. S. Ricalton.
1992.
Western blotting in evaluating Lyme seropositivity and the utility of a gel densitometric approach.
Neurology
42:2185-2192[Abstract/Free Full Text].
|
| 38.
|
Padula, S. J.,
R. Dias,
A. Sampieri,
R. B. Craven, and R. W. Ryan.
1994.
Use of recombinant OspC from Borrelia burgdorferi for serodiagnosis of early Lyme disease.
J. Clin. Microbiol.
32:1733-1738[Abstract/Free Full Text].
|
| 39.
|
Pollack, R.,
S. R. Telford III, and A. Spielman.
1993.
Standardization of medium for culturing Lyme disease spirochetes.
J. Clin. Microbiol.
31:1251-1255[Abstract/Free Full Text].
|
| 40.
|
Schmitz, J. L.,
C. S. Powell, and J. D. Folds.
1993.
Comparison of seven commercial kits for detection of antibodies to Borrelia burgdorferi.
Eur. J. Clin. Microbiol. Infect. Dis.
12:419-424[Medline].
|
| 41.
|
Schneider, T.,
R. Lange,
W. Ronspeck,
W. Weigelt, and H. W. Kolmel.
1992.
Prognostic B-cell epitopes on the flagellar protein of Borrelia burgdorferi.
Infect. Immun.
60:316-319[Abstract/Free Full Text].
|
| 42.
|
Schutzer, S.,
P. K. Coyle,
J. J. Dunn,
B. J. Luft, and M. Brunner.
1994.
Early and specific antibody response to ospA in Lyme disease.
J. Clin. Invest.
94:454-457.
|
| 43.
|
Schutzer, S.,
P. K. Coyle,
A. L. Belman,
M. G. Golightly, and J. Drulle.
1990.
Sequestration of antibody to Borrelia burgdorferi in immune complexes in seronegative Lyme disease.
Lancet
335:312-315[Medline].
|
| 44.
|
Schutzer, S. E.,
P. K. Coyle, and M. Brunner.
1992.
Identification of specific Borrelia burgdorferi components in circulating antigen-antibody complexes, p. 135-148.
In
S. E. Schutzer (ed.), Lyme disease: molecular and immunologic approaches. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 45.
|
Siegel, J. P., and J. S. Remington.
1983.
Comparison of methods for quantitating antigen-specific immunoglobulin M antibody with a reverse enzyme-linked immunosorbent assay.
J. Clin. Microbiol.
18:63-70[Abstract/Free Full Text].
|
| 45a.
|
Sigal, L. H.
1994.
Persisting complaints of Lyme disease: a conceptual review.
Am. J. Med.
96:365-374[Medline].
|
| 45b.
|
Sigal, L. H.
1998.
Special article: pitfalls in the diagnosis and management of Lyme disease.
Arthritis Rheum.
41:195-204[Medline].
|
| 46.
|
Simpson, W. J.,
W. Cieplak,
M. E. Schrumpf,
A. G. Barbour, and T. G. Schwan.
1994.
Nucleotide sequence and analysis of the gene in Borrelia burgdorferi encoding the immunogenic P39 antigen.
FEMS Microbiol Let.
119:381-388[Medline].
|
| 47.
|
Simpson, W. J.,
M. E. Schrumpf, and T. G. Schwan.
1990.
Reactivity of human Lyme borreliosis sera with a 39-kilodalton antigen specific to Borrelia burgdorferi.
J. Clin. Microbiol.
28:1329-1337[Abstract/Free Full Text].
|
| 48.
|
Sivak, S. L.,
M. E. Aguero-Rosenfeld,
J. Nowakowski,
R. B. Nadelman, and G. P. Wormser.
1996.
Accuracy of IgM immunoblotting to confirm the clinical diagnosis of early Lyme disease.
Arch. Intern. Med.
156:2105-2109[Abstract].
|
| 49.
|
Steere, A. C.
1989.
Lyme disease.
N. Engl. J. Med.
321:586-596[Abstract].
|
| 50.
|
Steere, A. C.,
R. L. Grodzicki,
A. N. Kornblatt,
J. E. Craft,
A. G. Barbour,
W. Burgdorfer,
G. P. Schmid,
J. Johnson, and S. E. Malawista.
1983.
The spirochetal etiology of Lyme disease.
N. Engl. J. Med.
308:733-740[Abstract].
|
| 51.
|
Tierno, P. M., and J. Cadet-Legros.
1996.
Methods comparison for diagnosis of Lyme disease.
Lab. Med.
27:542-546.
|
| 52.
|
Vejtorp, M.
1980.
The interference of IgM rheumatoid factor in enzyme-linked immunosorbent assays of rubella IgM and IgG antibodies.
J. Virol Methods
1:1-9.
|
| 53.
|
Yu, Z.,
J. M. Carter,
L. H. Sigal, and S. Stein.
1996.
Multi-well ELISA based on independent peptide-antigens for antibody capture: application to Lyme disease serodiagnosis.
J. Immunol. Methods.
198:23-25.
|
| 54.
|
Yu, Z.,
J. M. Carter,
H. Lackland,
L. H. Sigal, and S. Stein.
1996.
Presentation of peptide antigens as albumin conjugates for use in detection of serum antibodies by ELISA.
Bioconj. Chem.
7:338-342[Medline].
|
| 55.
|
Zoller, L.,
S. Burkard, and H. Schafer.
1991.
Validity of Western immunoblot band patterns in the serodiagnosis of Lyme borreliosis.
J. Clin. Microbiol.
29:174-182[Abstract/Free Full Text].
|
Journal of Clinical Microbiology, April 1998, p. 1074-1080, Vol. 36, No. 4
0095-1137/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Brunner, M., Marques, A. R., Hornung, R. L.
(2006). Report Refuting Value of Immune Complexes To Diagnose Lyme Disease Is Invalid. CVI
13: 304-306
[Full Text]
-
Marques, A. R., Hornung, R. L., Dally, L., Philipp, M. T.
(2005). Detection of Immune Complexes Is Not Independent of Detection of Antibodies in Lyme Disease Patients and Does Not Confirm Active Infection with Borrelia burgdorferi. CVI
12: 1036-1040
[Abstract]
[Full Text]
-
Brunner, M., Sigal, L. H.
(2001). Use of Serum Immune Complexes in a New Test That Accurately Confirms Early Lyme Disease and Active Infection with Borrelia burgdorferi. J. Clin. Microbiol.
39: 3213-3221
[Abstract]
[Full Text]
-
Schriefer, M. E., Dennis, D. T., Gubler, D. J., Hayes, E. B., Johnson, B. J. B., Chu, M. C., Schutzer, S. E., Holland, B., Reid, P., Coyle, P. K.
(2000). Serologic Testing for Lyme Disease. JAMA
284: 695-696
[Full Text]
-
Chattopadhyay, A., Nam, C., Dragomir-Daescu, D.
(1999). Delamination Modeling and Detection in Smart Composite Plates. Journal of Reinforced Plastics and Composites
18: 1557-1572
[Abstract]
Top
Abstract
Introduction
