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Previous Article | Next Article 
Journal of Clinical Microbiology, April 1999, p. 976-980, Vol. 37, No. 4
Department of Pathology,
Received 11 September 1998/Returned for modification 15 October
1998/Accepted 15 December 1998
The use of mailed, home-obtained urine specimens could facilitate
screening programs for the detection of asymptomatic Chlamydia trachomatis infections. Since transport time could have an
adverse effect on the sensitivity of C. trachomatis
detection by PCR, the influence of DNA degradation on amplification was
monitored over the course of 1 week. Therefore, urine specimens were
aliquoted on the day of collection or arrival. Two groups of urine
specimens were investigated. Group I contains first-void C. trachomatis-positive and -negative urine samples. DNA degradation
was monitored in group I samples for 7 days at room temperature (RT)
and at 4°C by amplifying different lengths of the human Chlamydia trachomatis
infection is a leading cause of sexually transmitted disease. Severe
sequelae such as pelvic inflammatory disease, ectopic pregnancy, and
tubal infertility can develop. Since many of these C. trachomatis infections run an asymptomatic course, there are often
no clinical signs or symptoms, and no intervention for the prevention
of these severe sequelae is possible. To have an impact on the
Chlamydia reservoir, identification and treatment of these
asymptomatic carriers are essential. However, the routine use of
cervical and urethral swabs in screening programs will hamper high
participation rates for asymptomatic, infected women and men. Recently,
commercially available DNA amplification systems like the Amplicor
system (PCR; Hoffmann-La Roche [9]) and the ligase
chain reaction (LCR; LCx, Abbott Diagnostic Division [4]) and the RNA amplification system AMP-CT
(Gen-Probe [15]) were introduced and can successfully
be used for the detection of C. trachomatis in urine
specimens. The use of urine specimens, which can be obtained by a
noninvasive technique, will result in a higher sensitivity compared
with that of cell culture of specimens from the urethra and a slightly
lower sensitivity compared with that of detection by amplification
techniques with cervical scrapings from symptomatic, infected women
(2, 6, 12, 18). Furthermore, the use of urine specimens
saves time and money for both the participants of screening programs
and the physicians of gynecology departments or general practitioners. The use of mailed, home-obtained urine specimens may have further important implications for the feasibility and cost of screening programs for young asymptomatic women and men. However, the use of
mailed urine specimens could result in lower sensitivities of the
different Chlamydia assays due to DNA degradation during the
time of nonrefrigerated mail transport, which mostly takes several
days. As shown by Østergaard et al. (14), a lower
sensitivity of tests with home-obtained urine specimens was reported,
but no analysis of nucleic acid stability during transport was performed.
Therefore, the effect of DNA degradation in urine specimens was
investigated over the course of 1 week by monitoring the PCR amplification of different lengths of the human Clinical specimens. (i) Group I specimens for monitoring DNA
degradation.
First-void urine specimens were obtained from 30 patients (10 were C. trachomatis negative and 20 were
C. trachomatis positive) (group I specimens). C. trachomatis-positive urine specimens (as assessed with the
Amplicor and LCx systems were obtained during a screening program with
asymptomatic women in Amsterdam, The Netherlands. The specimens were
obtained before treatment (which was delivered at a second visit) and
were directly transported for analysis.
(ii) Group II specimens for monitoring mailed, home-obtained
urine specimens.
C. trachomatis-positive first-void urine
specimens (group II specimens; n = 21 [from 13 females
and 8 males]) were derived from patients who participated in a
screening program for asymptomatic C. trachomatis infections.
Monitoring DNA degradation in group I specimens.
Ten
C. trachomatis-negative and 10 C. trachomatis-positive urine specimens were aliquoted into two
series of seven 1.5-ml batches of urine on the day of collection. One
series of seven aliquots was kept at room temperature and the other was
kept at 4°C. The first sample (day 1) of each series was pelleted (10 min, 14,000 rpm), and DNA was isolated (as described previously [13]) to create an inhibition-free background for PCR
purposes. Each day from days 2 to 7 one sample of each series was
pelleted and the DNA was isolated. Furthermore, from a third group
consisting of 10 C. trachomatis-positive urine specimens, a
series was frozen at Monitoring mailed, home-obtained urine specimens (group II
specimens).
To obtain C. trachomatis-positive urine
specimens, 700 asymptomatic persons were screened in Amsterdam.
Twenty-one urine specimens were positive for C. trachomatis
as determined by the LCx assay (Abbott) and the Amplicor PCR
(Hoffmann-La Roche). After arrival at the laboratory, the urine
specimens were vortexed, aliquoted, and stored at room temperature. For
the LCx assay and the Amplicor PCR, seven aliquots of 1 and 0.5 ml of
urine, respectively, were stored. On each day for 7 days one specimen
was pretreated according to each of the manufacturers' instructions
and was stored at PCR. (i) (ii) C. trachomatis.
The Chlamydia
plasmid target (155 bp) was amplified with primers pI6.1
(5'-AGAGTACATCGGTCAACGA-3'; antisense) and pI6.2.
(5'-TCACAGCGGTTGCTCGAAGCA-3'; sense). PCR was performed as
described previously (13). The amplified DNA was analyzed by
1.5% agarose gel electrophoresis and ethidium bromide staining.
Commercial assays.
Both the LCx (Abbott) and the Amplicor
(Hoffmann-La Roche) assays were performed as described by the
manufacturers for the detection of C. trachomatis DNA.
Furthermore, since no DNA degradation could be monitored, the optional
internal control which is coamplified with target nucleic acid
detection in the Amplicor assay was monitored for the evaluation of
test performance.
Monitoring DNA degradation.
Aliquots of 1.5 ml from group I
first-void urine specimens, which were transported directly on the day
of collection, were stored for 7 days. On each day, DNA from a 1.5-ml
aliquot of urine was isolated. DNA degradation was monitored by
amplification of different lengths of the
0095-1137/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Mailed, Home-Obtained Urine Specimens: a Reliable
Screening Approach for Detecting Asymptomatic Chlamydia
trachomatis Infections
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-globin
gene and the C. trachomatis plasmid target. DNA degradation
was observed only for the larger human -globin fragments at days 5 to 7 at RT. In contrast, at 4°C all targets could be amplified. Urine specimens were also frozen and thawed before aliquoting to mimic freezing during transport. This resulted in a lower sensitivity for the
detection of C. trachomatis after thawing and 3 to 4 days at RT. In addition, mailed, home-obtained C. trachomatis-positive urine specimens (group II) were analyzed for
7 days after arrival by two commercially available C. trachomatis detection systems (PCR and ligase chain reaction
[LCR]). The C. trachomatis plasmid target in mailed,
home-obtained urine specimens could be amplified by both PCR and LCR
after 1 week of storage and/or transport at RT. In conclusion, our
findings indicate that mailed, home-obtained urine specimens are
suitable for the sensitive detection of asymptomatic C. trachomatis infections by amplification methods, even if the transport time is up to 1 week at RT. These findings support the feasibility and validity of screening programs based on mailed, home-obtained urine specimens. Larger studies should be initiated to
confirm our results.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-globin gene and the
chlamydial plasmid target (group I). For this purpose, pure DNA was
isolated from urine specimens (group I) to generate an inhibition-free
background for amplification. Furthermore, the results that were
obtained were used to investigate the suitability of the use of mailed,
home-obtained urine specimens (group II) for the detection of
asymptomatic C. trachomatis infections by commercially
available amplification methods (LCR [LCx; Abbott] and PCR
[Amplicor; Hoffmann-La Roche]) over the course of 1 week.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
20°C and was then thawed to mimic freezing
during transport. The specimens were subsequently aliquoted and handled
as described above. To check for DNA degradation, human -globin and
C. trachomatis PCRs were performed.
20°C pending analysis.
-Globin.
To check for DNA degradation, human
-globin PCRs were performed with primers BGPCO3.1
(5'-ACACAACTGTGTTCACTAGC-3'; sense) and BGPCO5
(5'-GAAACCCAAGAGTCTTCTCT-3'; antisense), BGPCO6
(5'-CATCAGGAGTGGACAGATCC-3'; antisense), and BGPCO7
(5'-GAAAACATCAA-GGGTCCCAT-3'; antisense), which generated
amplimers of 209, 326, or 509 bp, respectively (3, 10). The
amplified DNA was analyzed by 1.5% agarose gel electrophoresis and
ethidium bromide staining.
RESULTS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
-globin gene.
-Globin PCR results for a representative C. trachomatis-negative urine specimen are shown in Fig.
1 (panels 1A and 1B). When the specimens
were stored at room temperature (Fig. 1, panel 1A), the 209-bp
-globin fragment could be amplified for up to 7 days. The 509-bp
fragment was no longer amplified at days 5 to 7 (only 3 of 10 samples
were very weakly positive on day 5, as shown in Fig. 1, panel 1A), and
the 326-bp fragment was almost invisible at the gel level by day 7. In
contrast, when the specimens were stored at 4°C (Fig. 1, panel 1B),
even at day 7 the 326- and 509-bp fragments could still be amplified.
However, it appears that at day 7 the 509-bp fragment is beginning to
fade, possibly indicating the start of degradation, whereas the smaller
fragments did not fade.
View larger version (68K):
[in a new window]
FIG. 1.
Monitoring of DNA degradation in urine specimens (group
I) by PCR for 7 days. (1A and 1B) Results of PCR for the detection of
the human -globin gene in a urine specimen stored at room
temperature and 4°C, respectively. (2A and 2B) Results of PCR for the
detection of the C. trachomatis plasmid target in a C. trachomatis-positive urine specimen stored at room temperature and
4°C, respectively. (3A and 3B). Results of PCR for the detection of
the C. trachomatis plasmid target in a C. trachomatis-positive urine specimen which was initially frozen and
thawed and subsequently stored at room temperature and 4°C,
respectively. The marker (lanes M) is pUC 19 HinfI. The
different amplimer lengths are indicated with arrows.
-globin PCR results for C. trachomatis-positive urine
specimens were equal to the results obtained for the C. trachomatis-negative urine specimens.
Plasmid PCR results for a representative C. trachomatis-positive urine specimen which was initially frozen at
20°C are shown in Fig. 1 (panels 3A and 3B). At 4°C (Fig. 1,
panel 3B) the C. trachomatis plasmid target was successfully
amplified after up to 1 week of storage. On the other hand, after
storage at room temperature (Fig. 1, panel 3A) after 3 to 4 days, a
decrease in the sensitivity was seen, as indicated by a weaker amplimer
signal after gel electrophoresis. Also, the -globin PCR product of
209 bp amplified less efficiently at days 3 to 7, and longer fragments could not be amplified.
Monitoring mailed, home-obtained urine specimens.
The mailed,
home-obtained C. trachomatis-positive urine specimens
(n = 21) in group II were monitored daily for the
amplification of the Chlamydia plasmid target by the LCx
(Abbott) and Amplicor (Hoffmann-La Roche) assays for 1 week after
arrival at the laboratory. The mean transport time for these urine
specimens was 3.7 days (range, 1 to 6 days). The results are shown in
Table 1. To visualize the degree of
positivity without using the optical density values, strongly positive
and weakly positive results were determined, as indicated in Table 1.
Up to 1 week after arrival at the laboratory, all but one of the urine
specimens were positive for C. trachomatis by both assays.
The exception was sample 9, for which the optical density was elevated
(but below the cutoff) by the LCx assay on day 7. Among the 21 urine
specimens, 5 urine specimens (specimens 3, 9, 12, 19, and 20) were not
strongly positive but had weakly positive signals most of the time.
Furthermore, even after 7 days at room temperature most samples were
still positive for C. trachomatis. For two samples,
transport to the laboratory and storage at room temperature even took
12 days, and strongly positive signals were still generated by the
commercially assays. Since no DNA degradation could be monitored, the
internal control of the Amplicor assay was used to monitor whether
inhibition arose during storage at room temperature. After transport
and subsequent storage for 7 days at room temperature, no inhibition of
amplification occurred.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
|
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This study strongly suggests that mailed, home-obtained urine specimens are suitable for the sensitive detection of asymptomatic C. trachomatis infections by amplification methods (LCx and Amplicor assays) even if the transport time is up to 1 week at room temperature. In all 21 mailed, home-obtained, C. trachomatis-positive urine specimens (group II), the Chlamydia plasmid target could be successfully amplified even after a week at room temperature. These findings have the potential to change the feasibility of screening programs for the detection of asymptomatic C. trachomatis infection.
Pure DNA was isolated from the group I specimens for the monitoring of
DNA degradation and for C. trachomatis detection for 1 week
to investigate if whether C. trachomatis DNA could still be
detected reliably. As shown for this group of specimens, small DNA
fragments could still be amplified from DNA isolated from nonfrozen
urine specimens after 1 week of storage at room temperature. This was
shown by the detection of the -globin PCR fragment of 209 bp and the
detection of the C. trachomatis plasmid PCR fragment of 155 bp. This explains the successful amplification of the C. trachomatis plasmid target by the commercially available assays, which generated by the Amplicor PCR a 207-bp fragment (9)
and by the Abbott LCx assay a 145-bp fragment (4).
Furthermore, Chlamydia elementary bodies are more resistant
to DNase activity than the human -globin target, as shown previously
(11), indicating an enhanced stability of the
Chlamydia target in comparison to that of the human
-globin target.
Degradation of the DNA in the group I urine specimens was shown after 5 days by the inability to amplify the largest -globin fragment tested
(509 bp). With storage of the specimens at 4°C the larger -globin
fragments could be amplified up to day 7. This can be explained by the
fact that DNase activity is substantially higher at room temperature
than at 4°C. When the urine specimens were frozen during transport, a
reduction in sensitivity was seen only when the specimens were
subsequently stored at room temperature for several days, but no
reduction in sensitivity was observed during subsequent storage at
4°C. This is probably due to the inhibition of the cellular DNase
which is derived from the freezing and thawing of the cells in the
urine samples. Since commercial assays were used for the group II
specimens, no -globin PCRs could be performed with the commerical
buffer sample solution to check the possibility that inhibitory factors
could emerge during storage at room temperature. However, this was not
the case, as shown by the generation of a positive result for the internal standard which is incorporated in the Amplicor assay.
With the group II specimens it was shown that even after 7 days at room temperature most samples were still positive for C. trachomatis. Weakly positive samples might be missed when mailed, home-obtained urine specimens are tested. However, this is unlikely, since five urine specimens which were weakly positive remained positive for 1 week. Furthermore, a dilution series (10-, 100-, and 1,000-fold dilutions) was made from two samples that arrived at the laboratory on the day of collection, and C. trachomatis detection was performed for 1 week (data not shown). Both samples diluted 100-fold were still positive after 1 week. These results strongly indicate that weakly positive signals for this asymptomatically infected population will not be missed in a screening based on mailed, home-obtained urine specimens.
The use of specimens collected off-site and transport to the laboratory for the detection of sexually transmitted diseases has been described previously, but endocervical specimens (8) and tampon-collected specimens (20) were used. Recently, a study with mailed, home-obtained specimens for the detection of C. trachomatis showed that C. trachomatis infections could be detected as effectively with all urogenital specimens excluding urine specimens as with samples collected by general practitioners (16). In that study, by Østergaard et al. (16), a lower sensitivity of the LCR assay used for the mailed, home-obtained urine specimens was reported. Nonrefrigerated mailing conditions were given as a possible explanation. However, the urine specimens were obtained in Denmark from 15 January 1995 to 15 February 1996, a period probably comprising winter conditions with temperatures below 0°C. Our findings suggest that if some of these urine specimens transported under nonrefrigerated conditions were frozen and thawed, the lower sensitivity was possibly due to freezing and thawing rather than the nonrefrigerated transport conditions, since the latter should not result in a lower sensitivity, as shown in the present study. Since freezing and thawing of urine samples followed by storage at room temperature can result in a lower sensitivity, the use of mailed, home-obtained urine specimens during winter periods should be well controlled with regard to the transport time.
Mailed, home-obtained urine specimens were evaluated in a setting for the implementation of screening in The Netherlands. For some other countries with higher temperatures the influence of transport temperatures should be evaluated again. However, it is unlikely that different results will be obtained from such a study since, as mentioned before, the C. trachomatis elementary body is quite resistant to DNase activity.
The performances of the AMP-CT (Gen-Probe [15]) RNA amplification system and nucleic acid sequence-based amplification (NASBA) assay (13) with mailed, home-obtained urine specimens were not evaluated. Since, besides reticulate bodies, elementary bodies also contain copies of RNA, it should be possible to amplify RNA. Using the NASBA RNA amplification system (13), we have shown that it is possible to detect C. trachomatis RNA after arrival at the laboratory (unpublished data). Furthermore, Østergaard et al. (17) have shown that C. trachomatis RNA could be detected in mailed, home-obtained urine specimens by the AMP-CT RNA amplification assay. However, no data with respect to transport times and conditions for RNA detection are yet available.
The effects of programs for selective screening for C. trachomatis infection have clearly been demonstrated in the United States and Scandinavia (7, 19). Gen
and Mårdh
(4) reported that screening by DNA amplification assays,
combined with treatment of positive patients with azithromycin and
partner notification, is the most cost-effective screening strategy for
women. Although cost-benefit analyses are needed (5, 14,
16), the reliable use of mailed, home-obtained urine specimens
could have important implications for the choice of the most beneficial
screening strategy for the detection of asymptomatic C. trachomatis infections. Implications of home sampling have been
studied for home sampling versus conventional contact tracing for the
detection of C. trachomatis infection (1) and is
being evaluated with large groups of asymptomatic women and men in the
region of Amsterdam.
This study has been conducted in a research setting, but if actual screenings for C. trachomatis infections are to be initiated with mailed, home-obtained urine specimens, larger studies should be initiated to confirm the preliminary results obtained in this study. Although our data for group II specimens strongly indicate that these assays can reliably be used for screening for the detection of C. trachomatis infections, companies should evaluate their commercially available assays for this purpose. A study that uses a parallel submission should be designed; that is, half of the sample would be tested immediately after collection and the other half would be held and/or mailed. The study should be done in such a way that a statistical comparison of the results could be performed.
In conclusion, home-obtained urine specimens are suitable for use for the sensitive detection of asymptomatic C. trachomatis infections by commercially available amplification methods (LCx and Amplicor assays), even if the transport time is up to 1 week at room temperature. These results might have important implications for the feasibility of widespread surveys for the detection of chlamydial disease, but further investigations with larger study groups should be performed to confirm the results obtained in the present study.
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ACKNOWLEDGMENTS |
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This work was partly supported by grants 28-2588 and 28-1182-1 from the Prevention Fund of The Netherlands.
We thank T. Klop and H. Los for technical assistance.
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FOOTNOTES |
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* Corresponding author. Mailing address: Department of Pathology, Section of Molecular Pathology, University Hospital Vrije Universiteit, De Boelelaan 1117, 1081 HV, Amsterdam, The Netherlands. Phone: 31-20-4440503 or 31-20-4444023. Fax: 31-20-4442964. E-mail: vandenbrule{at}azvu.nl.
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Materials and Methods
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Discussion
References
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