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BMJ. 2010; 340: c1040.
Published online Mar 11, 2010. doi:  10.1136/bmj.c1040
PMCID: PMC2837143

HPV testing on self collected cervicovaginal lavage specimens as screening method for women who do not attend cervical screening: cohort study

Murat Gök, research fellow,1 Daniëlle A M Heideman, molecular biologist,1 Folkert J van Kemenade, surgical pathologist,1 Johannes Berkhof, medical statistician,2 Lawrence Rozendaal, surgical pathologist,1 Johan W M Spruyt, gynaecologist,3 Feja Voorhorst, gynaecologist,1 Jeroen A M Beliën, senior researcher,1 Milena Babović, manager of regional screening organisation,4 Peter J F Snijders, medical biologist ,1 and Chris J L M Meijer, surgical pathologistcorresponding author1

Abstract

Objective To determine whether offering self sampling of cervicovaginal material for high risk human papillomavirus (HPV) testing is an effective screening method for women who do not attend regular cervical screening programmes.

Design Cohort study (the PROHTECT trial).

Settings Noord-Holland and Flevoland regions of the Netherlands, December 2006 to December 2007, including 13 laboratories, gynaecologists, and more than 800 general practitioners.

Participants 28 073 women who had not responded to two invitations to the regular cervical screening programme: 27 792 women were assigned to the self sampling group and invited to submit a self collected cervicovaginal sample for HPV testing; 281 were assigned to the recall control group and received a second re-invitation for conventional cytology.

Intervention Women with a positive result on the high risk HPV test on their self sample material were referred to their general practitioner. Women with abnormal results on cytology were referred for colposcopy. Women with normal results on cytology were re-evaluated after one year by cytology and high risk HPV testing and referred for colposcopy if either result was positive.

Main outcome measures Attendance rate in both groups and yield of cervical intraepithelial neoplasia grade II/III or worse (≥CIN II/≥CIN III) in self sampling responders.

Results The compliance rate in the self sampling group was significantly higher than in the control group (crude 26.6% v 16.4%, P<0.001; adjusted 27.5% v 16.6%, P<0.001). The number of detected ≥CIN II and ≥CIN III lesions in self sampling responders was 99 (1.3%) and 76 (1.0%), respectively. Self sampling responders who had not participated in the previous round of screening (43%) had increased relative risks of ≥CIN II (2.04, 95% confidence interval 1.27 to 3.28) and ≥CIN III (2.28, 1.31 to 3.96) compared with self sampling women who had been screened in the previous round (57%).

Conclusions Offering self sampling by sending a device for collecting cervicovaginal specimens for high risk HPV testing to women who did not attend regular screening is a feasible and effective method of increasing coverage in a screening programme. The response rate and the yield of high grade lesions support implementation of this method for such women.

Trial registration ISRCTN45527158.

Introduction

The introduction of organised cervical cancer screening programmes in Western countries has contributed to a decrease in incidence of and mortality from cervical cancer. Nevertheless, one major problem concerning the effectiveness of current cervical screening programmes remains non-attendance.1 2 3 4

Non-participating women (that is, non-attendees) are at increased risk of cervical cancer.5 6 Therefore, targeting non-attendees is important in achieving optimal protection from screening programmes. Offering self sampling of cervicovaginal material for screening has been suggested as a way of increasing screening compliance.1 7 8

Cytomorphological evaluation of self sampled cervicovaginal specimens for detection of high grade cervical lesions has been shown to be inferior compared with cervical samples obtained by a physician. Conversely, high risk HPV testing on self collected cervicovaginal samples had at least similar sensitivity for cervical intraepithelial neoplasia grades II/III or worse (≥CIN II/≥CIN III) compared with cytological reading of a corresponding cervical sample collected by a physician.9 10 11 12

Methods

Patients and procedures

PROHTECT (protection by offering HPV testing on cervicovaginal specimens trial) is a cohort study within the setting of the Dutch population based cervical screening programme to assess the feasibility and efficacy of offering cervicovaginal lavage self sampling for high risk HPV testing to women who do not attend the regular screening programme. In the Dutch screening programme, women aged 30-60 are invited once every five years. Non-attendees living in the counties of Noord-Holland or Flevoland (n=28 073) who had received their screening invitation in 2005 were selected from the regional health council registry. In the screening programme women are asked to make an appointment to have a smear taken by their general practitioner or assistant. Opportunistic smears are disregarded but results are registered in the nationwide pathology database (PALGA). There is no charge for women participating in primary cervical screening, but the costs for the necessary follow-up in cases of abnormal cytology can be recovered from health insurance companies. A “non-attendee” was defined as a woman who neither responded to the regular invitation nor to a standard reminder after six months. Women with previous hysterectomy were excluded.

With a computerised random number generator non-attendees were assigned in a 99:1 ratio to either receive a kit (Delphi Screener (previous Pantarhei-Screener/Mermaid)) to collect cervicovaginal material for subsequent testing for high risk HPV hybrid capture II (self sampling group, n=27 792) or to receive a second recall for conventional cytology (recall control group, n=281). The Delphi Screener is a lavage device, designed to rinse the upper vagina and cervix and, in combination with HPV testing, has been shown to allow detection of similar high grade yields of CIN to those achieved in cervical smears collected by physicians.9 The skewed ratio ensured adequate power to detect a higher attendance rate in the self sampling versus second recall arm, while at the same time maximising the ≥CIN II/≥CIN III rate among self sampling responders. The pre-randomised self sampling and recall cohorts were recruited from December 2006 to April 2007, and women were invited to respond within six weeks after the mailing. Only responses received up to December 2007 were scored for analysis.

All invited women were written to at their home address the week before to give notice of receipt of a second recall letter (recall control group) or a self sample kit (self sampling group). Women in the recall control group received an official second reminder to visit their general practitioner for conventional cytology, an explanatory letter, and an informed consent form. Women in the self sampling group received a self sample kit with an explanatory letter,9 a collection tube, instructions (written and drawn), an informed consent form, and a return box with the address of the testing laboratory. A telephone helpline and website providing information on the trial (www.hpvthuistest.nl) was available throughout the study.

HPV testing and follow-up algorithm

Women in the self sampling group were asked to send the collection tube containing their cervicovaginal lavage specimen with the signed informed consent form to the laboratory for high risk HPV testing. Each specimen was tested with the hybrid capture II high risk HPV DNA method at the laboratory. The results of the confirmatory HPV samples taken by general practitioner (see below) were also based on the hybrid capture II tests. On arrival in the laboratory, lavage specimens were concentrated by spinning down, removing all supernatant, and resuspending the pellet in universal collection medium. If no clear cell pellets were visible, samples were considered invalid for testing. In such cases, the woman was sent a second kit to repeat the self sampling at home. Valid samples were subjected to the hybrid capture II high risk HPV DNA test in an automated format on a rapid capture system), according to the manufacturer’s instructions (Qiagen, Gaithersburg, MD, USA). This test is designed to detect high risk HPV types 16, 18, 31, 33, 35, 39, 45, 51, 52, 56, 58, 59, and 68. Results were expressed as relative light units per cut-off value (RLU/CO). Women with a positive result (RLU/CO ≥1) were instructed to visit their general practitioner for their doctor to take a cervical sample for cytology and confirmatory HPV testing in the regional laboratory serving the general practitioner. Women with abnormal cytology results (threshold borderline or mild dyskaryosis) were referred for colposcopy. Cytology of cervical smears taken by the physician was carried out in local laboratories, and results were reported according to the CISOE-A classification, the standard classification system for cytology in the Netherlands, which can easily be translated into the Bethesda classification.10 In brief, on the basis of either squamous or columnar abnormalities, cytology results are categorised into three groups (normal, borderline or mild dyskaryosis, and moderate dyskaryosis or worse). Borderline or mild dyskaryosis corresponds in the Bethesda classification to ASCUS\LSIL. Endometrial abnormalities were excluded.

Independent of the HPV test result on the specimen taken by the physician, women with normal cytology results received advice for repeat testing (cytology and HPV testing) after a year and were referred for colposcopy in case of a positive HPV or cytology test result (threshold ≥borderline or mild dyskaryosis). Women with negative results on both tests were referred back to the national screening programme as their risk of a clinically relevant lesion was considered too low to warrant referral for colposcopy.11 Colposcopy directed biopsies were taken for histological examination from suspected areas on the cervix according to standard procedures in the Netherlands.12 13 Histological examination was done in local pathology laboratories and specimens were classified as CIN 0 (that is, within normal limits or including any non-neoplastic lesion such as inflammation, cyst, etc), I, II, or III, or as invasive cancer, according to international criteria.14 15 On the basis of biopsy results, women were treated in accordance with the guidelines of the national screening programme.16 Based on the cytology results, participating women in the recall control group were managed according to the guidelines of the national screening programme.17

Statistical analysis

Power calculation

For the power calculation, we estimated the population of non-attendees in the study area to be 45 000 in the year 2005. We further assumed 10% of these women would not be eligible and that the response rate in the self sampling group would be 15% higher than in the recall control group. The power calculation was based on our previous pilot,1 which showed compliance rates of 17.6% and 31.5% in the recall control and self sampling groups, respectively (two sided t test; α 0.05; 99:1 randomisation; power 0.99999). We chose a 99:1 randomisation to provide sufficient power to detect differences in compliance and to maximise the yield of ≥CIN II/≥CIN III in the self sampling cohort.

Response rate

All trial data were managed within a customised database. The self sampling response was counted on the basis of receipt of informed consent forms plus self samples, and the response of the recall control group was counted on the basis of receipt of informed consent forms as well as through the nationwide network and registry of histopathology and cytopathology in the Netherlands (PALGA; Bunnik, Netherlands). For computing the response rate we included all women who responded actively within 12 months after their invitation to participate in this trial and compared response rates of the groups with χ2 test. In addition to the crude response rates, we also compared the response rates adjusted for women who during the study reported they were not eligible because of previous hysterectomy.

HPV prevalence and yield of high grade CIN and cervical cancer

Only self sampling material sent in within a year after the invitation was included in HPV prevalence analysis. The 18 month cumulative yields of ≥CIN II and ≥CIN III in women in the self sampling group who submitted a specimen were obtained through the PALGA database. If necessary, physicians were contacted directly for additional clinical data.

Assessment of screening history self sampling responders

Programmed screening in the Netherlands involves seven cytology invitations during a lifetime to women aged 30-60—that is, every five years. The PALGA database provided the screening history of attendees in the two groups.18 In analysing the screening history among the women who had been invited for a previous round of screening (that is, those aged ≥34), women were considered to have missed the previous screening round if a smear sample had not been taken within the past seven years.

Risks of ≥CIN II and ≥CIN III were calculated for women aged ≥34 who did not participate in the previous round relative to those who were screened in the previous round. The relative risks were adjusted for age by the Mantel-Haenszel method, with age stratified at 34-38, 39-43, 44-48, 49-53, 54-58, and ≥59. Women aged ≤33 could not have a screening history because of their age and were excluded. The association between the relative risks and age, as well as between the relative risks and screening history, were tested by the Mantel-Haenszel test of homogeneity.

Results

Characteristics of trial cohort

Figures 1 and 2 show the flow of women through the studystudy .. The public health database indicated that 28 073 women in the 2005 cohort who received an invitation to screening in the study area were registered as non-attendees, instead of the expected 45 000. Of these, 27 792 were allocated to the self sampling arm and 281 to the recall control arm. During the study 906 women (3.3%) in the self sampling group and four women (1.4%) in the recall control group reported having had a hysterectomy, leaving 26 886 eligible women in the self sampling group and 277 in the recall control group. There were no significant differences between the age distributions in both arms.

figure gokm683060.f1_default
Fig 1 Study design for comparison of compliance rates between recall control group and self sampling group
figure gokm683060.f2_default
Fig 2 Study design for evaluation of yield of ≥CIN II in women of self sampling group (BMD=borderline or mild dyskaryosis)

Participation rate

In the self sampling group, 7404 of 27 792 (26.6%) women sent a self sampled specimen for HPV testing and 51 (0.2%) decided to visit their general practitioner for conventional cervical cytology. When we adjusted for women who were not eligible because of hysterectomy, the percentage of women who responded by submitting a self sample was 27.5%. The self sampling response rate did not vary with age (Pearson χ2=7.15, df=6; P=0.307).

In the recall control group, 46 of 281 (16.4%) women visited their general practitioner for cervical cytology. After adjustment for non-eligibility, the response rate was 16.6% (46/277). Taken together, the difference in compliance rates between the groups was 10.2% (26.6% v 16.4%, 95% confidence interval 5.9% to 14.6%, P<0.001) or 10.9% (27.5% v 16.6%, 6.5% to 15.3%, P<0.001) after adjustment for those who were not eligible.

To evaluate whether screening history had an effect on participation in women allocated to self sampling, we compared the screening history of women in the recall control group (n=277) with women in the self sampling group (n=26 886). When we excluded women aged <33 because they could not have a screening history (49 in the recall control group and 3398 in the self sampling group), 228 eligible women were left in the recall control group and 22 988 in the self sampling group. There were 34 and 6227 attendees aged ≥34, respectively. Of the 228 women in the recall control group, 61 (26.8%) had had a smear taken in the past seven years, compared with 5967 (26.0%) of the 22 988 women in the self sampling group, indicating no significant differences.

We examined the effect of having no smear in the past seven years on attendance of women in the recall control group compared with the effect on attendance in the self sampling group. In the recall control group 9.0% (15/167) of the women responded to recall compared with 15.8% (2694/17 021) of the women in the self sampling group. Thus, the relative risk for participation of women without a smear in the past seven years in the self sampling group was 1.76 (1.09 to 2.86) compared with women who had no smear in the past seven years in the recall control group (P=0.016).

For the women who had had a smear in the past seven years, these proportions were 19/61 (31.1%) for the recall control group and 3533/5967 (59.2%) for the self sampling group, resulting in a relative risk of participation in the self sampling group of 1.90 (1.31 to 2.76, P<0.001). As the relative risks of participation of women who had or had not had a smear in the past seven years did not differ (1.90 v 1.76, P=0.80), it seems unlikely that screening history introduced bias in the participation of women in self sampling in both groups.

HPV detection rate self sampling attendees

Of the 7404 women who submitted a self collected sample, 7384 (99.8%) had a valid hybrid capture II test result (fig 1)1) and 757 (10.3%) were positive for high risk HPV (fig 2)2).. The percentage positive for HPV decreased with age (t=−6.77; P<0.001) until age 39-43, when a plateau was reached (t=−0.30; P=0.77).

Women who had positive results for high risk HPV were advised to visit their general practitioner for both conventional cytology and a second high risk HPV test on a cervical sample collected by the physician. A valid HPV result was recorded for 491, and 288 (58.7%) were positive for cervical HPV. Of the 203 with a negative result, 81 (39.9%) originally displayed hybrid capture II RLU/CO values <2 on the self collected sample. Conversely, only 21 (7.3%) with a positive result had a RLU/CO value <2 on the self sample.

Compliance with follow-up

Of the self sampling attendees with positive HPV results, 90.4% (684/757) complied with follow-up with their general practitioner. Of these 684, 437 (63.9%) followed the trial protocol and had both cytology and HPV test results, whereas 61 (8.9%) had only an HPV test and 186 (27.2%) had only a cytology test. Thus 623/757 (82%) women had cytological follow-up. A total of 182 (26.6%) women had abnormal results on cytology, of whom 150 (82.4%) adhered to the direct referral advice for colposcopy. The 502 remaining women (73.4%) were advised have a repeat testing after a year on a sample collected by their general practitioner, and 287 (57.2%) complied. Based on a positive high risk HPV result or cytology result, or both, 65 (12.9%) women were advised to undergo colposcopy and 25 (38.5%) of them did so.

Yield of high grade CIN and cervical cancer

Among the 150 women with ≥borderline or mild dyskaryosis who visited a gynaecologist at baseline, 94 ≥CIN II lesions were detected, including five invasive carcinomas. Furthermore, five ≥CIN II lesions were detected among the 25 women who complied with the referral for colposcopy after repeat testing at one year. The cumulative 18 month yields of ≥CIN II and ≥CIN III in women with a positive HPV self sampling test were 1.3% (99/7384) and 1.0% (76/7384), respectively (table 11).

Table 1
 Yields of ≥CIN II/III in women who carried out cervical self sampling (categorised by age)

Yield of high grade CIN and cervical cancer in relation to screening history

Among women aged ≥34, those who did not have a cervical smear taken at the previous round had more ≥CIN II (relative risk 2.04, 1.27 to 3.28, P=0.003; table 22)) and more ≥CIN III (2.28, 1.31 to 3.96, P=0.003; table 33)) than women who did have a cervical smear at the previous round. This association between screening history and cervical intraepithelial neoplasia was not related to age (P values Mantel-Haenszel test of homogeneity 0.639 for ≥CIN II and 0.515 for ≥CIN III). All five carcinomas were detected in women aged ≥34 who had not been screened at the previous round.

Table 2
 Yield and risk of ≥CIN II in women aged ≥34 in relation to participation in previous round of screening (categorised by age)
Table 3
 Yield and risk of ≥CIN III in women aged ≥34 in relation to participation in previous round of screening (categorised by age)

Discussion

In the Netherlands in 2005, 65% of women attended the cervical screening programme (annual report of the regular screening programme, 2006, www.bevolkingsonderzoek.info/). By offering self sampling to non-attendees, and taking into account the 18% loss of cytology in the follow-up in this group, the real effect on attendance in the screening programme would be an extra 5.2% (6.3% (27.5% of 23%)*(100%−18%)). The total attendance in the screening programme would then increase to 70.2% (5.2%+65%). Moreover, we showed that the cumulative incidence of ≥CIN II yield in our study was 1.3% (99/7384), while the CIN lesions found via regular screening programme in 2005 was 0.8% (data received from PALGA).

Screening history of non-attendees

The finding of a twofold and more than twofold relative risk of ≥CIN II and ≥CIN III, respectively, in self sampling women aged ≥34 who did not attend the previous screening round is in line with the assumption that background risk for ≥CIN II/≥CIN III is increased after women miss one screening round. In the self sampling group, the association between screening history and CIN was independent of age (P=0.639 for ≥CIN II and 0.515 for ≥CIN III).

Strengths and limitations

We did not include a recall control group for comparison of yield of ≥CIN II/≥CIN III with the self sampling group because data from our previous work indicated that non-attendees of the regular screening programme respond poorly to any repeat invitation letter.1 Instead, we used a randomisation ratio of self sampling versus recall women in favour of maximising detection of ≥CIN II/≥CIN III in the self sampling group to allow an accurate assessment of the yield achieved by self sampling combined with HPV testing in non-attendees.

A potential bias in our attendance data could be that, unlike responders to a re-invitation for cytology, self sampling responders might have been more likely to respond for curiosity reasons, despite already being opportunistically screened before the study invitation. To address this we analysed the effect of screening history on participation via self sampling versus a second recall. When we took into account the screening history of women responders aged ≥34 in both arms, there was no indication that previously screened women would have a relatively higher preference for self sampling than women who were not screened within the past seven years.

Interestingly, self sampling responders showed high adherence to direct follow-up regimens, both at the general practitioner level (90.4%) and at the level of direct referral for colposcopy (94.5%). In size the latter is comparable with follow-up compliance of attendees of the Dutch screening programme (91%).16 Compliance after repeat testing advice (59% of women attended after one year), however, was markedly lower than observed in regular screening attendees with similar advice (86%).19 This rather low return rate might be influenced by the fact that most of these women had previous normal cytology test results after a smear taken by a physician.

In 41% of the women who had an HPV test on both self and physician collected samples, a positive result for high risk HPV in the self sample could not be confirmed in the sample taken by the physician. Most of these discrepant test results were found in women with low hybrid capture II RLU/CO values. In self sampled specimens more HPV infections of vaginal origin, including those of low risk HPV types, might be detected by hybrid capture II.20 21 22 23 24 25 Even with a cut-off level of a positive result on hybrid capture II increased to RLU/CO ≥2, there are still discrepancies between positive results for HPV in the self sampled specimens and smears taken by the general practitioner. In that case the total number of HPV positive cases would decrease from 757 to 627, but we would miss six ≥CIN II lesions (two ≥CIN II, and four ≥CIN III).

Interestingly, the yields of ≥CIN II and ≥CIN III in self sampling responders who attended the previous round and the yields in regular screening responders of the same age tested for high risk HPV by general primer 5+/6+ polymerase chain reaction (GP5+/6+ PCR) were identical (0.8% and 0.5%, respectively).26 27 This strongly suggests that the ≥CIN II/≥CIN III sensitivity of HPV testing in self sampled cervicovaginal material is not inferior to that of HPV testing on smears taken by a physician. This is in agreement with a recent meta-analysis that indicated that self sampling is as sensitive as physician obtained sampling to detect high risk HPV.25 Collectively, our data show that targeted efforts should be made to screen self sampling non-attendees who missed a previous screening round, given their increased risk of clinically relevant cervical disease.

We have also shown that the chosen triage algorithm of a cytology test on a conventional smear after an HPV positive self sample is successful. A substantial subset of the 10% self sampling women who were positive for high risk HPV, however, seemed to have negative cytology results and be negative for high risk HPV at follow-up, which in practice resulted in a marked number of unnecessary visits to the general practitioner for these women. Therefore, alternative triage tools applicable to self sampled material should be considered to prevent redundant sampling by general practitioners. In this context, molecular methylation markers,28 which are currently being investigated, are highly promising when applied to self sampled specimens. Furthermore, efforts are ongoing to improve liquid based cytological preparations of cervicovaginal lavage fluids for detecting abnormal cells.

Conclusions

It is feasible and effective to offer women who do not attend regular cervical screening programmes the choice of self sampling by sending a device for collecting cervicovaginal specimens for high risk HPV testing. This should lead to increased coverage and marked detection of ≥CIN II/≥CIN III lesions, particularly in women who have not attended the previous round of screening. Implementation is likely to pay off immediately in terms of protecting a subset of non-attendees known to be at increased risk of cervical cancer.

What is already known on this topic

  • More than half of cervical carcinomas in countries with population based screening are diagnosed in women not complying with the cervical screening programme
  • Offering self sampling of cervicovaginal material for screening has been suggested as a way of increasing compliance with screening

What this study adds

  • Offering high risk HPV testing on self sampled cervicovaginal material for HPV testing to non-responder women results in increased rates of compliance
  • The yield of >CIN II/>CIN III in non-responder women is significantly higher than in regular responder women, indicating that this group of women is at increased for cervical cancer

Notes

We thank research staff and technicians of the unit of molecular pathology, VU University Medical Center, Amsterdam, for HPV DNA testing and logistics, the cytotechnicians for cytological testing and logistics, and the administrative coworkers and the information technology team of the department of pathology, VU University Medical Center, Amsterdam, for their supportive work. We are grateful for the active participation in the trial of cytology laboratories of the Academic Medical Center, Onze Lieve Vrouwe Gasthuis, Slotervaart Ziekenhuis and HistoPathologisch anatomisch laboratorium (all in Amsterdam), IJsselmeer ziekenhuis (Lelystad), Leids Cytologisch en Pathologisch Laboratorium (Leiden), Medisch Centrum Alkmaar (Alkmaar), Kennemergasthuis (Haarlem), Tergooiziekenhuizen (Blaricum), Spaarne Ziekenhuis (Hoofddorp), Stichting Artsenlaboratorium/trombosedienst (Saltro: Utrecht), Westfries Gasthuis (Hoorn), and Zaans Medisch Centrum (Zaandam). In addition we acknowledge cooperation with local health councils and over 800 general practitioners and their assistants, who contributed to the care of the women involved. We also thank the gynaecologists for their part in this trial and PALGA for retrieving cytological and histological results and screening histories.

Contributors: CJLMM was the project leader and designed the study with DAMH, FJvanK, PJFS. MG, DAMH, FJvanK, JB, CJLMM, LR, FV, and PJFS drafted the manuscript. MG and JB analysed the data; JB was responsible for the data analyses. LR and JAMB were responsible for database management. DAMH, PJFS, and CJLMM were responsible for HPV DNA testing. MB was responsible for the screening register of the Regional Screening Organisation Database. JS was responsible for communication with gynaecologists. FJvanK was responsible for coordination of cytological testing at the individual laboratories. All authors had full access to all of the data in the study and can take responsibility for the integrity of the data and the accuracy of the data analysis, and critically reviewed the manuscript and approved the final version. CJLMM is guarantor.

Funding: The study was partly funded by Delphi Bioscience (formerly Pantarhei Devices), Scherpenzeel, Netherlands, and Zeist, Netherlands, who also provided the self sampling kits, and the screening organisation Noord-Holland and Flevoland, and IKA (Comprehensive Cancer Center Amsterdam). Hybrid capture II kits and universal collection medium were provided by Qiagen, Gaithersburg, MD, USA.

Competing interests: All authors have completed the Unified Competing Interest form at www.icmje.org/coi_disclosure.pdf (available on request from the corresponding author) and declare that (1) CJ M, and PJF S have support from Delphi Bioscience B.V. Scherpenzeel, Netherlands, and Qiagen, Gaithersburg, USA, for the submitted work; (2) CJ M, PJ S, and DA H have relationships with Self-screen and CJ M has a relationship with Qiagen that might have an interest in the submitted work in the previous 3 years; (3) their spouses, partners, or children have no financial relationships that may be relevant to the submitted work; and (4) none of the authors have non-financial interests that may be relevant to the submitted work. The sources of funding did not have any influence on the design and the analysis of the results.

Ethical approval: This study was approved by the national ethics committee (Ministry of Public Health No 2006/01WBO) and informed consent was given by all women.

Data sharing: No additional data available.

Notes

Cite this as: BMJ 2010;340:c1040

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