Objectives: To evaluate the cost effectiveness of a systematic screening programme for asymptomatic Chlamydia trachomatis infections in a female inner city population. To determine the sensitivity of the cost effectiveness analysis to variation in the probability of developing sequelae.
Methods: A decision tree was constructed to evaluate health effects of the programme, such as averted sequelae of chlamydial infection. Cost effectiveness from a societal perspective was estimated for screening by means of a ligase chain reaction on mailed, home obtained urine specimens, in a population with a C trachomatis test prevalence of 2.9%. An extensive sensitivity analysis was performed for the probability of sequelae, the percentage of preventable pelvic inflammatory disease (PID), and the discount rate.
Results: The estimated net cost of curing one woman, aged 15–40 years, of a C trachomatis infection is US$1210. To prevent one major outcome (PID, tubal factor infertility, ectopic pregnancy, chronic pelvic pain, or neonatal pneumonia), 479 women would have to be screened. The net cost of preventing one major outcome is $15 800. Changing the probability of PID after chlamydial infection from 5% to 25% decreases the net cost per major outcome averted from $28 300 to $6380, a reduction of 78%. Results were less sensitive to variations in estimates for other sequelae. The breakeven prevalence of the programme ranges from 6.4% for the scenario with all probabilities for complications set at the maximum value to a prevalence of 100% for probabilities set at the minimum value.
Conclusions: Systematic screening of all women aged 15–40 years for asymptomatic C trachomatis infections is not cost effective. Although the results of the analyses are sensitive to variation in the assumptions, the costs exceed the benefits, even in the most optimistic scenario.
- cost effectiveness analysis
- Chlamydia trachomatis
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Genital infections caused by the bacteria Chlamydia trachomatis are the most common sexually transmitted infections in industrialised countries. In women, C trachomatis can cause urethritis, cervicitis, pelvic inflammatory disease (PID) and, at a later stage, tubal factor infertility (TFI), ectopic pregnancy (EP), and chronic pelvic pain (CPP).1, 2 When giving birth an infected woman can pass the infection on to her child, who can develop a neonatal conjunctivitis or pneumonia as a result of the infection.3
Since genital chlamydial infection causes no or few symptoms, many infections remain undetected. Delayed treatment increases the risk of sequelae and transmission to sex partners. Screening is therefore indicated to prevent the spread of C trachomatis and also to prevent complications. Research in the United States and Sweden has shown that the detection and treatment of asymptomatic infections in women results in a reduction of complications.4, 5
Cost is an important factor, which should be taken into consideration before a screening programme is implemented. Cost effectiveness analyses of opportunistic screening programmes, focusing on patients attending healthcare clinics, or specific high risk groups, have shown that screening becomes cost effective at prevalences ranging from 2% to 6%.6–8 The introduction of sensitive DNA detection methods to test non-invasive specimens, such as urine, and the testing of mailed home obtained samples makes it possible to extend screening beyond the traditional settings.9–12 The cost effectiveness of systematic screening programmes in the general population has not been evaluated.
In most cost effectiveness studies to date the costs of organising the screening, including administrative costs, have not been included in the analysis. Furthermore, although some studies mention the imperfect specificity of the test, no study has taken the cost of follow up of false positive test results into account in the analysis. So far, only one study has reported a sensitivity analysis of risk estimates, although estimating the probability of complications based on the available literature leaves much room for variation.7
This paper reports on the cost effectiveness of a systematic screening programme for asymptomatic C trachomatis infections in women registered in general practice, based on mailed home obtained urine specimens. The sensitivity of the cost effectiveness analysis to variation in the probability of developing PID, EP, TFI, and CPP was determined.
A random sample of 5541 women, aged 15–40 years, was selected from the computer registers of 16 inner city general practices in Amsterdam. Between November 1996 and October 1997 these women were invited by their general practitioner to participate in the screening programme. Coded research material was sent to the home address of potential participants. Participants were requested to mail a first void, first stream urine sample and a completed questionnaire to the department of pathology in a prestamped addressed envelope, which was included in the material.
The study has been approved by the medical ethics committee of the Vrije Universiteit in Amsterdam.
DIAGNOSIS OF INFECTION
Urine samples were tested for the presence of C trachomatis by means of the ligase chain reaction (LCR) (Abbott Laboratories, Chicago, IL, USA) in the laboratory of the department of pathology of the University Hospital Vrije Universiteit.9–12 Tests were performed according to the instructions of the manufacturer.
The test results were reported back to the general practitioners, who were instructed to treat infected patients with a single dose of 1000 mg azithromycin, or erythromycin for pregnant women (4 × 500 mg for 5 days).
CHARACTERISTICS OF PARTICIPANTS
Fifty per cent of the women who were invited participated in the screening programme; 25% of the participants were of non-Dutch origin. Of all participating women, 120 had never been sexually active. The prevalence of asymptomatic infection, as determined by means of the LCR on urine for women aged 15–20 years, 21–25 years, 26–30 years, 31–35 years, and 36–40 years was 2.4%, 4.4%, 2.8%, 2.5%, and 2.2%, respectively.
DECISION TREE ANALYSIS
Figure 1 is a diagram of the decision tree used in the analysis. The sensitivity of the LCR on urine was estimated to be 85%, and the specificity 99%.9, 10 The assumptions for the risk of an untreated C trachomatis are listed in table 1. The risk of developing sequelae if treatment fails is assumed to equal the risk if a woman has not been tested or treated effectively.
As shown in figure 1 and table 1, the probability of pregnancy wish is age specific.15 This was included in the model to estimate how many women would develop an EP or consult a specialist for TFI. In addition, only women who gave birth while infected with C trachomatis were included in calculations of the probability of having a child with neonatal conjunctivitis or neonatal pneumonia.15 For the infectious period, an average of 52 weeks was assumed.16
The administrative costs and the costs of the materials sent to all women who were invited, were taken into account in the model (table 2).
Based on the workload reported by participating practices, it was estimated that the programme could be coordinated by two social nurses, both working full time. The recruitment costs for the programme have to be calculated for all women who were invited, since the material was not only sent to participants, but to all eligible women. The cost of recruitment is the sum of the cost of a urine container, an envelope, and postage (approximately US$0.50). For participants, a cost of $17.29 is included for return postage, and test and laboratory costs. The costs of follow up of an infected woman include the cost of one visit to a general practitioner, pharmacotherapy costs, and the pharmacist's fees. Treatment costs are also included for women with a false positive test result, although treating these women will not prevent any sequelae.
The cost estimates for sequelae are based on research carried out by Postma et al.17 It was assumed that 75% of women with symptomatic PID are treated on an outpatient basis,18 involving two visits to a GP, medication, a test for C trachomatis, and a test for Neisseria gonorrhoea. It is assumed that the remaining 25% are treated on an inpatient basis for 9.6 days 18, involving a diagnostic laparoscopy and medication.19
With regard to infertility, 66% of the women were assumed to seek evaluation, 20% of whom are evaluated in an inpatient setting.20 In vitro fertilisation (an average of 2.11 attempts) was assumed to occur in 23% of the infertile women evaluated.
Chronic pelvic pain was assumed to be treated with analgesic drugs, and with pelvic ultrasonography and ambulatory laparoscopy for 75% of the patients.6 Furthermore, outpatient treatment was assumed to involve 10 appointments with a physician (three with a GP, seven with a gynaecologist). The assumption for inpatient care was two appointments with a gynaecologist and hospitalisation for the same duration as inpatient treatment of PID, preceded by one visit to a GP. Seventy per cent of cases of chronic pelvic pain were assumed to be treated on an outpatient basis, and 30% on an inpatient basis.6 Owing to lack of reliable information surgery was not taken into consideration.
Neonatal conjunctivitis was assumed to involve tests for C trachomatis and N gonorrhoea and medication. The assumption for outpatient care for neonatal pneumonia was one visit to a GP, two visits to a paediatrician, a test for C trachomatis, and medication. One visit to a GP and 13 days of intensive inpatient hospital care was assumed for 10% of cases of neonatal pneumonia.6, 18
Deflators for the gross domestic product (GDP) were used to recalculate all costs in 1996 prices. Costs were converted into US$ on the basis of the GDP purchasing power parity (1 US$ = 2.07 Dutch guilders).21 Estimated costs of a hospital inpatient day for intensive neonatal care are $1159.22 The costs of accommodation for a “normal” hospital inpatient day were estimated at $304.23 Fees for examinations and treatment were used to cost hospital activities (data provided by the Academic Hospital in Groningen). The cost of one in vitro examination was estimated at $1423,20 and the costing of medication was based on market prices for standard prescriptions.24 The weighted average GP charge for publicly and privately insured patients is $15.51.25
The indirect costs of C trachomatis infections were estimated by applying the friction costs approach. To calculate a value for the loss of productivity from paid work, the average labour costs according to age and sex were used to approximate the net product. Based on an analysis of the labour costs in the Netherlands, the average gross income by age and sex were adjusted and inflated to derive the average labour costs applicable in the Netherlands in 1996.15, 26 They were multiplied by the employed labour force participation rate, specified according to age and sex, which yielded the net product per capita from paid work.15 Based on data obtained from the literature, 10 days of productivity were estimated to be lost for each case of treatment for PID or chronic pelvic pain. Moreover, 21 days were estimated to be lost for each case of inpatient treatment for PID or chronic pelvic pain and 28 days for each case of ectopic pregnancy.7 Assuming that an ambulatory visit costs half a working day and an appointment with a GP 1.5 hours, the loss of productivity due to infertility management (5 days, 4.5 hours for outpatient management, 4.5 days for inpatient management), and in vitro fertilisation (4 days) was computed. Indirect costs due to the loss of unpaid work were not taken into consideration.
SUMMARY OF COSTS
Table 2 presents a summary of the cost estimates. In the model, all future costs were discounted at a rate of 3% per year.27 The cost of complications in newborn babies and the cost of PID were assigned to the year of infection. It was assumed that costs for chronic pelvic pain occur 5 years after PID.7, 6 Costs for ectopic pregnancy and infertility are assumed to occur 10 years after C trachomatis infection in women aged 15–19, 5 years after infection in women aged 20–24, and 2 years after infection in older women.
The following screening strategies were taken into consideration: screening all women aged 15–25, as recommended by the guidelines of the Centers for Disease Control,19 and screening all women aged 15–40. The cost effectiveness of a screening strategy was calculated as a weighted average of age specific results, weighted by the age distribution of women in Amsterdam.
The cost effectiveness is presented for two denominators: a woman cured and a major outcome averted (MOA). A cured woman is defined as an asymptomatically infected woman, detected by the screening programme, who was effectively treated for C trachomatis. A major outcome is defined as either an episode of PID, CPP, EP, TFI, or neonatal pneumonia. Cost effectiveness is presented in a baseline analysis and in a sensitivity analysis.
Sensitivity analyses were performed for the probability of developing a PID after asymptomatic infection (range 5–25), the risk of developing TFI after PID (range 4–16), probability of developing chronic pelvic pain (range 10–20) and finally the probability of developing EP (range 4–16). The worst and best case scenario in terms of cost versus benefit were calculated by estimating the cost per major outcome averted with all the probabilities set at the minimum and maximum plausible values, respectively. Moreover, sensitivity analyses were applied to assumptions reflecting the preventable percentage of PIDs (from 75% to 25%), test sensitivity (from 85% to 90%), and discount rate (range 0–7%). Sensitivity analysis was limited to the net cost per MOA in the screening programme aimed at 15–40 year old women.
No sensitivity analysis was performed for the cost of the test, since a discount for large scale screening was already included in the calculations of the costs of the test.
Breakeven prevalences were calculated for screening with baseline assumptions, minimum probabilities, and maximum probabilities. The breakeven prevalence reflects the prevalence where the costs of screening (US$) equal those of averted healthcare costs.
As can be directly derived from the assumptions made, the probability of an infected woman being detected by the screening and being effectively treated is estimated at 73%. The overall test prevalence of 2.9%, found among women in Amsterdam corresponds with an estimated prevalence of 2.2%, corrected for sensitivity and specificity of the test assumed in the model. In a screening programme aimed at women aged 15–40 years, 889 women would have to be screened to prevent one major outcome. Given the current participation rate, approximately twice this number of women would have to be invited for screening. The implementation of screening for all women aged 15–40 years in Amsterdam (n=161 065) could prevent a total of 59 episodes of PID, three TFIs, six EPs, and nine cases of CPP, and could also prevent 13 cases of neonatal pneumonia from occurring as a result of chlamydial infection.
The net cost per woman cured for a screening programme directed at women aged 15–40 years is $1210 per woman cured (table 3).
Limiting the programme to women aged 15–25 years reduces the net cost per woman cured to $790. Net costs per MOA are $15 800 and $11 100, respectively.
The results of the sensitivity analyses are presented in table 4. Changing the estimate for the probability of developing PID after chlamydial infection from 5% to 25% decreases the cost per major outcome averted from $28 300 to $6380, a reduction of 78%. Similarly, plausible ranges for the probability of ectopic pregnancy, infertility, and chronic pelvic pain result in variations of 12%, 5%, and 7%, respectively. Changing the value of the percentage of PIDs that can be prevented by screening from 75% to 25% results in a 63% decrease in cost per major outcome averted. Assuming a further technical development of tests, a test sensitivity of 90% and a specificity of 99.9% were also taken into consideration. Increasing the assumed specificity resulted in a decrease in cost per major outcome averted from $15 800 to $9540, a decrease of 40%.
Finally, changing the discount rate from 0% to 7% results in an increase of 1% in cost per MOA.
Figure 2 shows the association between test prevalence and net cost per MOA of the programme aimed at women aged 15–40 years. The breakeven prevalence in the baseline analysis was 41.8%. The breakeven prevalences range from 6.4% for the best case scenario to 100% for the worst case scenario.
The breakeven prevalence of a programme aimed at women aged 15–25 ranges from 6.1% to 100% in the sensitivity analysis.
As a test prevalence of 2.9% was found among 15–40 year old women in Amsterdam, the range of cost per MOA, reflecting the range in probabilities, would be $1514 (maximum probabilities) to $48 604 (minimum probabilities). Similarly, at a test prevalence of 5%, the interval for net cost per MOA would range from $338 to $7485.
This is the first cost effectiveness analysis of a systematic, universal screening programme based on mailed home obtained urine specimens in the general population. The results show that the cost of a screening programme for women was found to exceed the benefits in both the baseline and the sensitivity analysis. Screening all women aged 15–40, under baseline assumptions, only becomes cost saving at a test prevalence of 41.8% or more.
The overall test prevalence in the study population was 2.9%. Cost effectiveness for the screening programme directed at women aged 15–40 years was estimated at $15 800 per MOA. Restriction of the programme to women aged 15–25 years lowers the net costs to $11 100 per MOA. Another frequently used outcome in cost effectiveness analyses of chlamydia screening is cost per PID averted. PID constitutes 66.3% of the cost per MOA at baseline.
Selective screening is one way of increasing the efficiency of screening. Several authors have suggested selective screening criteria for various settings.7, 8, 29 However, suitable selection criteria could not been identified for asymptomatic infections among the general population in Amsterdam30; thus, currently a comparison can only been made between a universal screening programme and no screening at all.
The risk estimates for chlamydial infection, used in the decision model, differ from estimates used in previous cost effectiveness analyses. Previous studies have used estimates for PID and tubal factor infertility of 25–30% and 10–12%, respectively.
However, no long term follow up studies of asymptomatic infections in a low prevalence population have yet been performed. Authors have based the estimates on studies among women with symptomatic infections, even though asymptomatic infections are most likely to be less virulent. In order to take that factor into account, lower estimates were used at baseline, and the estimates were varied over a wide range in the sensitivity analysis.
Similarly, the risk of a silent PID should be treated differently from the risk of an overt PID. Although several studies have attempted to study the association between silent PID and sequelae,31, 32 there is not insufficient evidence to quantify any association. Consequently, it was not possible to make a distinction between silent and overt PID in the analysis. Instead, the baseline probability of developing sequelae after PID was adjusted, and a sensitivity analysis was performed.
The results of the sensitivity analysis underscore the importance of valid risk estimation, since this can have a substantial impact on the outcome of the analysis. In this study, the cost per MOA was extremely sensitive to variations in the assumption reflecting the chance of developing PID. Increasing the estimate from 5% to 25% resulted in a 78% decrease in cost per MOA. A similar effect was seen when the percentage of preventable PIDs was changed from 75% to 25%. The model was also sensitive to the specificity of the test. No health gains or associated averted costs can be achieved among cases with a false positive test result; the costs decrease by 40% if the specificity of the test is estimated at 99.9% instead of 99%. Variations in the estimates for ectopic pregnancy, tubal factor infertility, chronic pelvic pain, test sensitivity, and discount rate had much less impact.
All costs have been estimated for the Netherlands and converted into US$. Cost in the model could reflect local differences in healthcare organisation and labour costs. Furthermore, the costs of health care and tests may change over time.
In the decision tree, the cost of all materials sent to participants and non-participants was included. Administrative costs, such as programme coordination, were also included. In practice, the costs will probably be higher, because of extra consultations for women who are worried about the potential consequences of the infection, the cost of media campaigns and other activities that would accompany the implementation of a programme. Furthermore, no physician fees for the screening were included, although other programmes—for example, influenza vaccination, that have been implemented in the Netherlands have included fees for physicians.33
In the analysis, complications of antibiotic treatment and referral and treatment of partners were not taken into consideration. Infected partners may reinfect females who have been screened, and can contribute to the spread of the infection in the population. It has been suggested recently, that men should always be included in a screening programme, and not just as “partners of infected women,”34 the reason for this being that targeting women only “stereotypes” them and affects their sexuality. Partner referral and screening aimed at men will be taken into account in a future evaluation of the effects of screening over time, using a more sophisticated dynamic model.
One hazard of cost effectiveness analysis is that it provides a unidimensional view of screening. The emphasis is placed on proving that the intervention is cost effective although, as this study shows, results can depend strongly on the assumptions included in a decision model. Moreover, other important aspects, such as invasion of privacy, psychological and social consequences of the test result, and the danger of medicalisation cannot be included in the model.
In conclusion, a universal screening programme for asymptomatic C trachomatis infections among 15–40 year old women is not cost effective. Although the results of the analyses are sensitive to variation in the assumptions, the costs exceed the benefits even in the most optimistic scenario.
The authors would like to thank all practices and patients for taking the time to participate in the screening. This study was supported by the Zorg Onderzoek Nederland (previously called the Prevention Fund) grants 28-2588 and 28-1182-1.
Conflict of interest: none
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