Date: Fri, 11 Aug 1995 11:18:00 +0500
From: ghmcleaf{CONTRACTOR/ASPEN/ghmcleaf}%NAC-GATEWAY.ASPEN@ace.aspensys.com
Subject: MMWR 08/11/95


MORBIDITY AND MORTALITY WEEKLY REPORT
******************************************
Centers for Disease Control and Prevention
August 11, 1995
Vol. 44, No. 31


    Laboratory Practices for Diagnosis of Tuberculosis --
                   United States, 1994
     The increase in cases of tuberculosis (TB) during 1985-1992
and the emergence of multidrug-resistant Mycobacterium tuberculosis
strains led to recommendations for rapid laboratory testing to
support control efforts and selection of proper therapy (1,2). Many
laboratories have adopted the recommendations to use rapid
acid-fast bacilli (AFB) smears, growth detection (i.e., primary
culture), identification, and drug-susceptibility testing for M.
tuberculosis (3). The regulations implementing the 1988 Clinical
Laboratory Improvement Amendments* (CLIA) require all laboratories
that perform any mycobacteriology testing to enroll in federally
approved proficiency testing (PT) programs. This report summarizes
information reported by the laboratories to PT programs in the
United States about their practices for M. tuberculosis.
     The PT programs submit samples of unknown content to
laboratories for testing in the same manner as actual patient
specimens; the laboratories subsequently report methods and test
results to the program. In 1994, the U.S. Department of Health and
Human Services approved six PT programs for mycobacteriology
testing: five programs (the College of American Pathologists [CAP];
the states of New Jersey, New York, and Wisconsin; and the
Commonwealth of Puerto Rico) provide PT testing for AFB smears,
growth detection, organism identification, and drug-susceptibility
testing; and one program (the American Association of Bioanalysts)
provides testing for AFB smears only.
     To determine the number of laboratories that performed various
levels of testing for M. tuberculosis, laboratories were classified
into four categories based on the practices specifically reported
for M. tuberculosis. These categories were laboratories that
perform 1) AFB smears and refer all specimens for primary culture
to another laboratory; 2) AFB smears and primary cultures for M.
tuberculosis but refer all AFB-positive culture isolates for
organism identification and drug-susceptibility tests; 3) AFB
smears and primary culture with identification of M. tuberculosis
isolates but refer isolates for drug-susceptibility testing; and 4)
AFB smears, primary culture, identification, and
drug-susceptibility testing for M. tuberculosis. Some laboratories
must enroll in more than one PT program to meet the requirements of
both state laboratory licensure programs and private laboratory
accreditation programs. Therefore, because most laboratories were
enrolled in the CAP PT program, the actual number of laboratories
in each of the four categories ranges from a minimum that
represents the enrollment of CAP only to a maximum that represents
the total reported enrollment for all PT programs.
     In 1994, a total of 2862 mycobacteriology laboratories were
enrolled in PT programs; 2459 (85%) were enrolled in CAP.
Category-specific enrollment ranged from 506 (CAP only) to 683 (all
PT programs) for laboratories that perform AFB smears only, 1126-1166 for
those that perform primary culture without organism
identification, 568-699 for those that perform primary culture and
identification, and 259-314 for those that perform primary culture,
identification, and drug-susceptibility testing (Figure 1).
     Of the 2862 mycobacteriology laboratories, 2179 reported
performing primary culture for M. tuberculosis. Of these, 1166
(54%) referred any AFB-positive isolates to another laboratory for
organism identification and drug-susceptibility testing, 699 (32%)
performed primary culture with identification, and 314 (14%)
performed primary culture, identification, and drug-susceptibility
testing. Similarly, of the 1953 laboratories enrolled in CAP only
that reported performing primary culture for M. tuberculosis, 1126
(58%) referred any AFB-positive isolates to another laboratory for
organism identification and drug-susceptibility testing, 568 (29%)
performed primary culture with identification, and 259 (13%)
performed primary culture, identification, and drug-susceptibility
testing.
Reported by: N Serafy, American Association of Bioanalysts,
Brownsville, Texas. N Kubala, G Woods, MD, College of American
Pathologists, Northfield, Illinois. M Salfinger, MD, I Salkin, PhD,
New York State Dept of Health. R La Fisca, New Jersey Dept of
Health. C Robles Rivera, Puerto Rico Dept of Health. N Bourdeau,
Univ of Wisconsin Center for Health Sciences, Madison. Div of
Laboratory Systems, Public Health Practice Program Office, CDC.
Editorial Note: Rapid laboratory testing to identify and determine
the drug susceptibility of M. tuberculosis isolates is vital to
effective diagnosis, treatment, and control of TB in the community.
The findings in this report indicate that for a substantial
proportion of TB cases, organism identification and
drug-susceptibility determinations may be delayed because at least
54% of laboratories performing primary cultures for M. tuberculosis
must refer AFB culture isolates to another laboratory for complete
analysis.
     Although both solid and liquid media together are recommended
for culturing M. tuberculosis, the liquid-culture method is needed
to rapidly isolate and detect the organism in primary culture and
to test susceptibility to the primary anti-TB drugs (1). In
addition to decreasing the time required to detect and isolate
mycobacteria, liquid-culture methods also increase the sensitivity
of culture for M. tuberculosis (1,4). Although primary
culture-isolation methods are not routinely reported to PT
programs, a 1992 survey of 749 laboratories that performed primary
culture with referral of all isolates to another laboratory
indicated that 97 (13%) were using the recommended liquid-culture
method (CAP, unpublished data, 1994). In addition, a survey of
hospital laboratories in 1992 indicated that only 35 (14%) of 248
laboratories that referred isolates for identification of M.
tuberculosis used the recommended liquid-culture method compared
with 139 (50%) of 280 laboratories that routinely identified
isolates of M. tuberculosis (CDC, unpublished data, 1994). Reasons
for the continued use of solid-culture medium alone may reflect
minimum test-volume requirements and higher costs associated with
the liquid-culture system.
     The exclusive use of solid-medium culture methods delays
isolation of M. tuberculosis by an average of 7-10 days (4),
thereby delaying organism identification to confirm diagnosis. In
addition, the referral of AFB-positive culture growth to another
laboratory may result in delays associated with transport. These
delays also may prolong determination of whether isolates are
resistant to anti-TB drugs: in 1994, based on test results for 28
states, 8% of cases were resistant to isoniazid (INH) and 2% were
resistant to both INH and rifampin (5). At least one state (i.e.,
New York) has regulations that prohibit laboratories from
performing primary culture if the laboratory does not perform
identification of M. tuberculosis.
     The findings in this report are subject to at least two
limitations. First, data were unavailable about the proportion of
all M. tuberculosis specimens tested by each of the four categories
of laboratories enrolled in PT programs. Second, data were
unavailable to determine whether laboratories that refer culture
isolates for identification have adopted use of liquid-culture
methods.
     Laboratories should select culture tests that provide rapid
identification of M. tuberculosis and drug-susceptibility test
results to enable early confirmation of the diagnosis and
initiation of infection-control measures and case-finding.
Laboratories that perform only primary culture for M. tuberculosis
should determine whether referral of the patient specimen, rather
than culture isolates, may decrease the time required for
identification and drug-susceptibility testing.
References
1. Tenover FC, Crawford JT, Huebner RE, Geiter LJ, Horsburgh CR Jr,
Good RC. The resurgence of tuberculosis: is your laboratory ready?
J Clin Microbiol 1993;31:767-70.
2. CDC. National action plan to combat multidrug-resistant
tuberculosis. MMWR 1992;41(no. RR-11).
3. Woods G, Witebsky F. Mycobacterial testing in clinical
laboratories that participate in the College of American
Pathologists Mycobacteriology E survey: results of a 1993
questionnaire. J Clin Microbiol 1995;33:407-12.
4. Nolte FS, Metchock B. Mycobacterium. In: Murray PR, Baron EJ,
Pfaller MA, Tenover FC, Yolken RH, eds. Manual of clinical
microbiology. 6th ed. Washington, DC: American Society for
Microbiology, 1995:400-37.
5. CDC. Tuberculosis morbidity--United States, 1994. MMWR
1995;44:387-9,395.

* 42 CFR 493.825.

Notice to Readers
Recommendations for Test Performance and Interpretation from the
Second National Conference on Serologic Diagnosis of Lyme Disease
     The Association of State and Territorial Public Health
Laboratory Directors, CDC, the Food and Drug Administration, the
National Institutes of Health, the Council of State and Territorial
Epidemiologists, and the National Committee for Clinical Laboratory
Standards cosponsored the Second National Conference on Serologic
Diagnosis of Lyme Disease held October 27-29, 1994. Conference
recommendations were grouped into four categories: 1) serologic
test performance and interpretation, 2) quality-assurance
practices, 3) new test evaluation and clearance, and 4)
communication of developments in Lyme disease (LD) testing. This
report presents recommendations for serologic test performance and
interpretation, which included substantial changes in the
recommended tests and their interpretation for the serodiagnosis of
LD.
     A two-test approach for active disease and for previous
infection using a sensitive enzyme immunoassay (EIA) or
immunofluorescent assay (IFA) followed by a Western immunoblot was
the algorithm of choice. All specimens positive or equivocal by a
sensitive EIA or IFA should be tested by a standardized Western
immunoblot. Specimens negative by a sensitive EIA or IFA need not
be tested further. When Western immunoblot is used during the first
4 weeks of disease onset (early LD), both immuno- globulin M (IgM)
and immunoglobulin G (IgG) procedures should be performed. A
positive IgM test result alone is not recommended for use in
determining active disease in persons with illness greater than 1
month's duration because the likelihood of a false-positive test
result for a current infection is high for these persons. If a
patient with suspected early LD has a negative serology, serologic
evidence of infection is best obtained by testing of paired acute-
and convalescent-phase serum samples. Serum samples from persons
with disseminated or late-stage LD almost always have a strong IgG
response to Borrelia burgdorferi antigens.
     It was recommended that an IgM immunoblot be considered
positive if two of the following three bands are present: 24 kDa
(OspC)*, 39 kDa (BmpA), and 41 kDa (Fla) (1). It was further
recommended that an that IgG immunoblot be considered positive if
five of the following 10 bands are present: 18 kDa, 21 kDa (OspC)*,
28 kDa, 30 kDa, 39 kDa (BmpA), 41 kDa (Fla), 45 kDa, 58 kDa (not
GroEL), 66 kDa, and 93 kDa (2).
     The details of both plenary sessions and the work group
deliberations are included in the publication of the proceedings,
which is available from the Association of State and Territorial
Public Health Laboratory Directors; telephone (202) 822-5227.
References
1. Engstrom SM, Shoop E, Johnson RC. Immunoblot interpretation
criteria for serodiagnosis of early Lyme disease. J Clin Microbiol
1995;33:419-22.
2. Dressler F, Whelan JA, Reinhart BN, Steere AC. Western blotting
in the serodiagnosis of Lyme disease. J Infect Dis 1993;167:392-400.

* The apparent molecular mass of OspC is dependent on the strain of
B. burgdorferi being tested. The 24 kDa and 21 kDa proteins
referred to are the same.