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Emerging Infectious Diseases
Volume 2, Number 2, April-June 1996

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Dispatches

Improved Serodiagnostic Testing for Lyme Disease: Results of a Multicenter
Serologic Evaluation

The diverse clinical manifestations of Lyme disease (1-3) have led to
frequent confusion in clinical diagnosis, a confusion compounded by
problems in the accuracy and precision of diagnostic serologic tests (4-11)
and the difficulty of isolating the causative organism (12-14), Borrelia
burgdorferi. In 1990, more than 20 commercially prepared serologic test
kits for Lyme disease were being sold in the United States, but no
nationally standardized reference test was available. A collaborative
evaluation of a selected sample of the commercial test kits by the Centers
for Disease Control and Prevention (CDC) and the Association of State and
Territorial Public Health Laboratory Directors (ASTPHLD) demonstrated poor
concordance of results among these test kits and among a selected group of
state health department laboratories (11). Because of the lack of a
rigorously defined reference serum panel, conclusions could not be drawn
about the sensitivity and specificity of the test kits evaluated. An
unexpected finding in this study was the low concordance in test results
between CDC and two consulting academic reference center laboratories. A
number of other studies also have demonstrated low concordance of Lyme
disease serologic test results obtained by a variety of laboratories
(4-10).

As a result of those findings, the study described here was designed to
fulfill the following objectives: 1) to assemble a serum panel from
patients who had clinically well-defined Lyme disease (preferably confirmed
by isolation of B. burgdorferi); healthy controls, and persons residing in
non–endemic-disease areas whose potentially cross-reactive specimens had
yielded equivocal ELISA results in earlier CDC tests; 2) to test this panel
in a blinded fashion by several recognized Lyme disease reference and
research laboratories; and 3) to compare the accuracy and precision of
tests as a prelude to developing national recommendations for standardized
serologic testing for antibodies to B. burgdorferi.

Tests were performed by five academic centers active in Lyme disease
research (the Marshfield Clinic, Marshfield, Wisconsin; University of
Medicine and Dentistry of New Jersey–Robert Wood Johnson Medical School,
New Brunswick, New Jersey; State University of New York at Stony Brook,
Stony Brook, New York; Tufts/New England Medical Center, Boston,
Massachusetts; and the University of Connecticut Health Center, Farmington,
Connecticut) and CDC’s Division of Vector-Borne Infectious Diseases,
National Center for Infectious Diseases, based in Ft. Collins, Colorado.

Serum samples from Lyme disease case-patients were obtained from the
participating academic investigators (n = 72) and from the CDC Lyme disease
reference serum collection (n = 37). All case-patient serum samples (total
= 109) were from patients who met the CDC clinical case definition for
surveillance of Lyme disease (15). The clinical manifestations in these
patients ranged from acute erythema migrans (EM) to late neurologic disease
accompanied by Lyme arthritis. B. burgdorferi had been cultured by the
method of Berger et al. from 14 of 34 (41%) acute-phase specimens provided
by CDC (14). Duplicate specimens (n = 85) were randomly selected from the
109 case-patient samples for precision analysis, making a total of 194
case-patient samples in the panel.

Control serum samples were provided by CDC from unpaid healthy blood donors
(n = 113) who resided in areas where Lyme disease is not endemic
(Cincinnati, Ohio, and Atlanta, Georgia; travel histories were not
available from these donors, however. Duplicate specimens (n = 87) also
were randomly selected, resulting in 200 noncase samples in the serum
panel. Additional control samples were obtained from persons who resided in
areas where Lyme disease was not endemic but whose physicians submitted
their serum for Lyme disease testing to CDC through their state health
department (n = 113). These specimens from patients with suspected cases
had borderline (equivocal) seroreactivity in the whole cell sonicate (WCS)
enzyme-linked immunoassay (ELISA)used by CDC before 1992 and are referred
to hereafter as “WCS-suspects” (16). The addition of duplicate specimens (n
= 87) brought this group to 200 equivocally seroreactive samples.

Serum was separated and frozen by the original collectors and shipped
frozen to CDC’s facilities in Ft. Collins, Colorado. The specimens were
divided into aliquots and coded; code labels were applied by CDC staff not
involved in serologic testing of the specimens (n = 594). The panels were
then refrozen and shipped on dry ice for blind testing by participating
investigators. All specimens were received frozen. To calculate test
sensitivity and specificity, only the result of the sample with the lower
random code number of each pair was used.

Each laboratory employed the testing method that it used routinely at the
time this study was undertaken (1992). CDC used an ELISA with a WCS antigen
prepared from highly passaged strain B31 (gift of A. Barbour, University of
Texas Health Sciences Center, San Antonio, Texas) and an ELISA with a
strain B31 flagellar antigen (FLA) then being evaluated (16, 17). The other
five participating investigators used ELISA tests that employed a WCS
antigen of B. burgdorferi. Four used assays developed in their own
laboratories, and one used a commercially available test kit (18-22). Three
investigators also tested all specimens by Western blotting using published
methods (19, 20). Two of these three performed immunoblotting for IgM and
IgG antibodies separately. One laboratory tested for IgM and IgG together.

Each participating laboratory submitted the raw data of its results, along
with a dichotomous interpretation of those results as either positive or
negative. By prior agreement, ELISA results that fell into a range
ordinarily reported as “equivocal” by that laboratory were treated as
negative for this analysis. Statistical analyses undertaken at CDC included
calculations of sensitivity (true positives correctly identified),
specificity (true negatives correctly identified), precision (frequency of
obtaining the same result on duplicate analysis of a specimen), and a
measure of concordance (agreement among investigators) of results among the
tests using the kappa statistic.

The accuracy and precision of the serologic tests as performed in 1992 by
all six laboratories is summarized in Table 1. The test methods of
investigators 1, 2, and 3 produced essentially equivalent results, with
moderately high sensitivity (73% to 79%) for the aggregate of all
case-patient samples tested and high specificity (98% to 99.5%). Precision
was high in these three laboratories for both blood donor samples (97% to
99%) and the WCS-suspects samples submitted from areas where Lyme disease
is nonendemic (94% to 98%). Precision was somewhat lower for the
case-patient samples (82% to 91%).

 Table 1. Accuracy and precision of serologic tests for Lyme disease
                          performed in 1992
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                    Accuracy (%)               Precision(%)
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                                         Case   Non-case-    WCS
 Investigator Sensitivity Specificity  patients patients  suspectsª
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 CDC
   (WCS)      93          71           93       77        69

 CDC
   (FLA)      92          82           92       79        62

  1           73          99.5         89       99        98

  2           76          99           82       99        97

  3           79          98           91       97        94

  4           49          91           79       94        93

  5           40          72           63       74        77
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 ª Specimens from patients with suspected cases that had borderline
 (equivocal) seroreactivity in an enzyme-linked immunosorbent assay
 with whole-cell sonicate antigen (WCS).
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The performance of the other three laboratories, including CDC’s, was poor.
Both CDC ELISA tests had high sensitivity (92% to 93%), but low specificity
(71% to 82%). Precision for case-patient specimens was fairly high (92% to
93%), but low for both non-case-patient (77% to 79%) and WCS-suspects
groups (62% to 69%). The method of investigator 4 gave very low sensitivity
(49%), moderately high specificity (91%), poor precision with Lyme disease
case-patient specimens (79%), but good precision with blood donor and
WCS-suspects samples (93% to 94%). Investigator 5, who used a commercial
test, obtained results with low accuracy and precision.

Concordance was high (kappa statistic 0.700) between the results of
investigators 1, 2, and 3. The CDC FLA test showed moderate concordance
(kappa 0.400) with results from investigators 1, 2, and 3. The results of
investigator 4 showed moderate concordance with those of investigators 1
and 2 (kappa 0.400) and low concordance (0.400) with the other results. The
results of investigator 5 had low concordance with all other results. The
CDC WCS test showed moderate concordance with the FLA test, but low
concordance with results of the ELISA tests of the other laboratories.

The three investigators with the best results all used Western blot to
supplement their ELISA. Two of these three investigators submitted their
dichotomous test interpretation with and without using Western blot
results. The sensitivity improved by 20% for one investigator and by 30%
for the other when Western blot results were included. The improvement
resulted from identifying as positive by Western blot those case-patient
specimens from which an equivocal result was obtained by ELISA and which by
study design would have been counted as negative by ELISA results alone.
Specificities were not affected by Western blot analysis in this group of
three investigators, since the serum panel in this study did not contain
cross-reactive sera; and the negative controls and WCS-suspects had
negative results by both ELISA and Western blot.

Test sensitivity from the three laboratories with the best test specificity
(98%) was analyzed according to the clinical manifestations in the
case-patients (Table 2). As expected, the sensitivities of the tests were
lowest in specimens from patients with early disease, 59% to 66% for
erythema migrans and 63% to 75% for early neurologic disease. Sensitivities
were much higher for samples of patients with late disease. Sensitivities
of 89% to 95% were obtained for Lyme arthritis patients and 91% to 100% for
persons with late neurologic disease, primarily encephalopathy or
polyneuropathy.

The emergence of a disease can outstrip the development of reliable methods
for its laboratory diagnosis. The serodiagnosis of Lyme disease has been
fraught with problems of precision and accuracy. This study provided an
opportunity for selected academic research centers and CDC to compare the
performance of their individual tests by using a serum panel from
clinically well-characterized patients and controls from
non–endemic-disease areas. The clinical diagnosis of early Lyme disease was
supported by the isolation of B. burgdorferi from skin biopsy specimens
(14), when possible. The panel, which was coded blind had a sufficiently
large number of samples (n = 335) to provide adequate statistical power for
the comparison.

  Table 2. Test sensitivity of laboratories demonstrating a
                   test specificity of 98%
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                            Sensitivity, % (positive
                                 samples/total)
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 Clinical            Laboratory   Laboratory   Laboratory
 Manifestations      1            2            3
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 Erythema migrans,
 all                 59 (55/94)   60 (56/94)   66 (62/94)

   Acute phasea      65 (11/17)   65 (11/17)   76 (13/17)

   Convalescent
 phaseb              57 (44/77)   58 (45/77)   64 (49/77)

 Carditis            100 (2/2)    100 (2/2)    100 (2/2)

 Lyme arthritisc     89 (58/65)   95 (62/65)   92 (60/65)

 Neurologic, all     85 (28/33)   88 (29/33)   91 (30/33)

   Early             63 (5/8)     63 (5/8)     75 (6/8)

   Late              91 (10/11)   100 (11/11)  91 (10/11)

   Late and
 arthritis           93 (13/14)   93 (13/14)   100 (14/14)
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 Total               74           77           79
                     (143/194)    (149/194)    (154/194)
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 a <=30 days from onset of erythema migrans to blood
 collection.
 b > 30 days from onset of erythema migrans to blood
 collection.
 c Without neurologic signs or symptoms.

Laboratories that supplemented their primary test, an ELISA, with
immunoblotting achieved greater test accuracy than those that did not. The
use of Western blot as a second test enabled the best performing
laboratories to increase test sensitivity without a concomitant loss of
specificity. This increase in sensitivity occurred as a result of
identifying as true positives by Western blot a number of those specimens
from patients with clinical cases of Lyme disease that were interpreted as
equivocal by ELISA and would have been otherwise considered in this study
as dichotomously negative results. Although the investigators employing
Western blot tested all panel specimens with this method, they did so at
that time to evaluate the potential value of Western blot in Lyme disease
serologic diagnosis.

The observation that Western blotting could be employed to resolve
equivocal ELISA results gave additional impetus for evaluating its
potential adjunctive role in Lyme disease serodiagnosis and eventually led
to the finally recommended two-test approach (23). The potential utility of
Western blotting, however, pointed out the lack of standardized methods for
producing blots and standardized interpretive criteria.

Performance of the CDC WCS and FLA ELISA in this study that did not include
known cross-reactive sera suggested that the positive cut-off value for
these tests was inappropriately low, thereby increasing sensitivity at the
expense of specificity. These results then explained the large number of
borderline WCS ELISA results obtained by CDC when it tested the sera of
patients residing in areas where Lyme disease was not endemic. This group
of WCS suspects was nearly uniformly found to be negative on ELISA by the
three laboratories with the best performance (Table 1) (23).

Specificity in this study was determined by testing specimens from blood
bank donors. With these samples, specificity in the three laboratories that
used immunoblotting was very high (98% to 99.5%). The test panel did not,
however, contain specimens frompatients with conditions known to produce
cross-reacting antibodies (e.g., syphilis) or polyclonal B-cell activation
(e.g., Epstein-Barr virus infection or systemic lupus erythematosus). Thus,
reported specificities in this study are likely higher than they would have
been if cross-reactive specimens were included in the evaluation.
Subsequent studies that included cross-reactive sera demonstrated that
Western blotting correctly identifies many false-positive ELISA reactions
(23, 24).

This study confirmed in the reference and research laboratory setting the
previously documented problems with accuracy and precision of
serodiagnostic tests by using WCS antigens of B. burgdorferi (4-11). The
study confirmed that a serious disparity existed between the test results
obtained by CDC and those obtained by academic reference centers with the
best testing performances. These results guided corrective action and led
to the adoption by CDC and ASTPHLD of a two-test approach to serodiagnosis
(23), which forms the basis for the future national standardization of Lyme
disease serologic testing methods.

Robert B. Craven,* Thomas J. Quan,* Raymond E. Bailey,* Raymond Dattwyler,†
Raymond W. Ryan,‡ Leonard H. Sigal,§ Allen C. Steere,¶ Bradley Sullivan,#
Barbara J.B. Johnson,* David T. Dennis,* and Duane J. Gubler*

*Centers for Disease Control and Prevention, Fort Collins, Colorado, USA;
†State University of New York at Stony Brook, Stony Brook, New York, USA;
‡University of Connecticut Health Center, Farmington, Connecticut, USA;
§University of Medicine and Dentistry of New Jersey–Robert Wood Johnson
Medical School, New Brunswick, New Jersey, USA; ¶Tufts/New England Medical
Center, Boston, Massachusetts, USA; #Marshfield Clinic, Marshfield,
Wisconsin, USA

A portion of this information was presented at the VIth International
Conference on Lyme Borreliosis, Bologna, Italy, June 1994 and at the Second
National Conference on Serologic Diagnosis of Lyme Disease, Dearborn,
Michigan, October 1994.

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