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Self‐certification versus physician certification of sick leave for reducing sickness absence and associated costs

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Background

From the societal and employers' perspectives, sickness absence has a large economic impact. Internationally, there is variation in sickness certification practices. However, in most countries a physician's certificate of illness or reduced work ability is needed at some point of sickness absence. In many countries, there is a time period of varying length called the 'self‐certification period' at the beginning of sickness absence. During that time a worker is not obliged to provide his or her employer a medical certificate and it is usually enough that the employee notifies his or her supervisor when taken ill. Self‐certification can be introduced at organisational, regional, or national level.

Objectives

To evaluate the effects of introducing, abolishing, or changing the period of self‐certification of sickness absence on: the total or average duration (number of sickness absence days) of short‐term sickness absence periods; the frequency of short‐term sickness absence periods; the associated costs (of sickness absence and (occupational) health care); and social climate, supervisor involvement, and workload or presenteeism (see Figure 1).

Search methods

We conducted a systematic literature search to identify all potentially eligible published and unpublished studies. We adapted the search strategy developed for MEDLINE for use in the other electronic databases. We also searched for unpublished trials on ClinicalTrials.gov and the World Health Organization International Clinical Trials Registry Platform (WHO ICTRP). We used Google Scholar for exploratory searches.

Selection criteria

We considered randomised controlled trials (RCTs), controlled before‐after (CBA) studies, and interrupted time‐series (ITS) studies for inclusion. We included studies carried out with individual employees or insured workers. We also included studies in which participants were addressed at the aggregate level of organisations, companies, municipalities, healthcare settings, or general populations. We included studies evaluating the effects of introducing, abolishing, or changing the period of self‐certification of sickness absence.

Data collection and analysis

We conducted a systematic literature search up to 14 June 2018. We calculated missing data from other data reported by the authors. We intended to perform a random‐effects meta‐analysis, but the studies were too different to enable meta‐analysis.

Main results

We screened 6091 records for inclusion. Five studies fulfilled our inclusion criteria: one is an RCT and four are CBA studies. One study from Sweden changed the period of self‐certification in 1985 in two districts for all insured inhabitants. Three studies from Norway conducted between 2001 and 2014 changed the period of self‐certification in municipalities for all or part of the workers. One study from 1969 introduced self‐certification for all manual workers of an oil refinery in the UK.

Longer compared to shorter self‐certificationfor reducing sickness absence in workers

Outcome: average duration of sickness absence periods

Extending the period of self‐certification from one week to two weeks produced a higher mean duration of sickness absence periods: mean difference in change values between the intervention and control group (MDchange) was 0.67 days/period up to 29 days (95% confidence interval (95% CI) 0.55 to 0.79; 1 RCT; low‐certainty evidence).

The introduction of self‐certification for a maximum of three days produced a lower mean duration of sickness absence up to three days (MDchange −0.32 days/period, 95% CI −0.39 to −0.25; 1 CBA study; very low‐certainty evidence). The authors of a different study reported that prolonging self‐certification from ≤ 3 days to ≤ 365 days did not lead to a change, but they did not provide numerical data (very low‐certainty evidence).

Outcome: number of sickness absence periods per worker

Extending the period of self‐certification from one week to two weeks resulted in no difference in the number of sickness absence periods in one RCT, but the authors did not report numerical data (low‐certainty evidence).

The introduction of self‐certification for a maximum of three days produced a higher mean number of sickness absence periods lasting up to three days (MDchange 0.48 periods, 95% CI 0.33 to 0.63) in one CBA study (very low‐certainty evidence).

Extending the period of self‐certification from three days to up to a year decreased the number of periods in one CBA study, but the authors did not report data (very low‐certainty evidence).

Outcome: average lost work time per 100 person‐years

Extending the period of self‐certification from one week to two weeks resulted in an inferred increase in lost work time in one RCT (very low‐certainty evidence).

Extending the period of self‐certification (introduction of self‐certification for a maximum of three days (from zero to three days) and from three days to five days, respectively) resulted in more work time lost due to sickness absence periods lasting up to three days in two CBA studies that could not be pooled (MDchange 0.54 days/person‐year, 95% CI 0.47 to 0.61; and MDchange 1.38 days/person‐year, 95% CI 1.16 to 1.60; very low‐certainty evidence).

Extending the period of self‐certification from three days up to 50 days led to 0.65 days less lost work time in one CBA study, based on absence periods lasting between four and 16 days. Extending the period of self‐certification from three days up to 365 days resulted in less work time lost due to sickness absence periods longer than 16 days (MDchange −2.84 days, 95% CI −3.35 to −2.33; 1 CBA study; very low‐certainty evidence).

Outcome: costs of sickness absence and physician certification

One RCT reported that the higher costs of sickness absence benefits incurred by extending the period of self‐certification far outweighed the possible reduction in costs of fewer physician appointments by almost six to one (low‐certainty evidence).

In summary, we found very low‐certainty evidence that introducing self‐certification of sickness absence or prolonging the self‐certification period has inconsistent effects on the mean number of sickness absence days, the number of sickness absence periods, and on lost work time due to sickness absence periods.

Authors' conclusions

There is low‐ to very low‐certainty evidence of inconsistent effects of changing the period of self‐certification on the duration or frequency of short‐term sickness absence periods or the amount of work time lost due to sickness absence. Because the evidence is of low or very low certainty, more and better studies are needed.

PICOs

Population
Intervention
Comparison
Outcome

The PICO model is widely used and taught in evidence-based health care as a strategy for formulating questions and search strategies and for characterizing clinical studies or meta-analyses. PICO stands for four different potential components of a clinical question: Patient, Population or Problem; Intervention; Comparison; Outcome.

See more on using PICO in the Cochrane Handbook.

Changing the length of time a worker is allowed to take time off work because of illness without a physician's certificate

What was the aim of this review?

To find out if it is possible to affect sickness absence by changing the length of time a worker is allowed to take time off work because of illness without a physician's certificate. We found five studies.

Key messages

We are uncertain whether changing the length of time a worker is allowed to take time off work because of illness without a physician's certificate has any effect on sickness absence, as the included studies reported very different results, and the certainty of the evidence was low to very low.

What was studied in the review?

Sickness absence prevents a person from working and thus may reduce income and causes costs to employers. Usually employers require a physician to certify sickness absence. This may not be meaningful in cases of less severe illnesses that pass quickly with rest. Self‐certification of sickness absence is already used at many workplaces for sickness absence periods lasting typically from one day up to two weeks. In this review, we evaluated how change in the length of the self‐certification period affects the mean number of sickness absence days, number of sickness absence periods, and the amount of lost work time at workplaces.

Why is this topic important?

Sickness absence is costly to society and to employers. Employers may have to continue paying the sick employee’s salary. After the employer’s obligation to pay has ended, insurance covers sickness benefits. Changing the practice of sickness certification in short sickness absences is expected to change employees' attitudes and behaviour, co‐operation and climate at the workplace, and diminish sickness absence. Self‐certification makes more healthcare resources available for other purposes.

What are the main results of the review?

We found five studies conducted between 1969 and 2014. One study evaluated the effect of prolonging the self‐certification period among all insured workers in a large city and a region in Sweden in 1988. Three studies evaluated the effect of prolonging the self‐certification period for employees of a few municipalities in Norway. One study evaluated the effect of introducing self‐certification in an organisation in the UK in 1969. The time participants in the intervention groups were allowed to be off work without a doctor's certificate ranged from three days to one year. The included studies measured the effects on the mean number of sickness absence days, the number of sickness absence periods, or on lost work time due to sickness absence periods. All studies compared the effect of the change with practice‐as‐usual.

Effects on duration of sickness absence periods

Extending self‐certification from one week to two weeks increased the mean duration of sickness absence. Introducing self‐certification for a maximum of three days reduced the mean duration of sickness absences lasting up to three days. Extending self‐certification from one to three days up to a year did not change the duration of sickness absence.

Effects on number of sickness absence periods

Extending self‐certification from one week to two weeks did not change the number of sickness absence periods. Introducing self‐certification for a maximum of three days increased sickness absence periods lasting up to three days. Extending self‐certification from three days to up to a year decreased sickness absence periods.

Effects on lost work time

Extending self‐certification from one week to two weeks resulted in an inferred increase in lost work time. Extending self‐certification (from zero days to three days and from three days to five days) increased the amount of work time lost due to sickness absence periods lasting up to three days. Extending self‐certification from ≤ 3 days to ≤ 50 days and from ≤ 3 days to ≤ 365 days reduced lost work time due to sickness absence periods of 4 to 16 days and > 16 days.

Costs of sickness absence and physician certification

The costs of sickness absence benefits resulting from a longer period of self‐certification may be about six times greater than the possible reduction in costs of fewer physician appointments.

How up‐to‐date is this review?

We searched for studies up to 14 June 2018.

Authors' conclusions

Implications for practice

Overall, we found low‐ to very low‐certainty evidence of inconsistent effects of self‐certification of sickness absence on the examined outcomes.

Implications for research

Given the inconsistency and very low‐certainty of the evidence identified, and the widespread practice of self‐certification of sickness absence, further studies are needed.

As the example of Hesselius 2005 shows, conducting randomised trials in this area is possible. To prevent confounding and selection bias, studies should employ randomisation. The preferred study design is cluster‐randomisation to prevent 'contamination' of intervention and control workers, as reported by Hesselius 2013. If a non‐randomised design is used, participants in the intervention and control groups should have similar age and sex distributions and work in the same industrial sector, and have similar sickness absence compensation schemes (e.g. similar waiting‐day practices). Study authors should reportthe number of participants in both the intervention and control groups and their age, sex,occupation, level of education, economic circumstance, disease status, and health behaviours, such as smoking, so as to judge the representativeness of the sample.

When the intervention consists of prolonged self‐certification periods, authors should report if this also implies restrictions on the use of occupational health services for these shorter absence periods. Control groups should include participants for whom there is no change in self‐certification practice until the end of intervention follow‐up.

Authors should report the effects on the number of short‐term sickness absence periods per worker, the duration of these periods, and the average lost work time. Outcomes must be measured similarly in both the intervention and control groups, which could be realised by including participants working for the same employer. Adverse outcomes such as overdiagnosis, overtreatment, and medicalisation of mild health symptoms and psychosocial problems should be considered if a physician's certificate is needed from the first day of absence.

For policymakers, the main implication from this Cochrane Review is that changes to current systems of sickness certification must be evaluated with a controlled study design to increase the evidence base on the effects of sickness certification.

Summary of findings

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Summary of findings for the main comparison. Longer self‐certification compared to shorter self‐certification for reducing sickness absence in workers

Longer self‐certification compared to shorter self‐certification for reducing sickness absence in workers

Patient or population: workers
Setting: work organisations
Intervention: longer self‐certification period
Comparison: shorter self‐certification period

Outcomes

Impact

№ of participants
(studies)

Certainty of the evidence
(GRADE)

RCT: Average duration of sickness absence periods in days
Follow‐up: 6 months

SC ≤ 14 days vs ≤ 7 days led to a 0.67 days longer duration of sickness absence periods ≤ 29 days (95% CI 0.55 to 0.79) in 1 study.

237,391
(1 RCT)

⊕⊕⊝⊝
LOW 1

CBA: Average duration of sickness absence periods in days
Follow‐up: 1 year

SC ≤ 3 days vs SC 0 days led to 0.32 days shorter duration of sickness absence periods ≤ 3 days (95% CI −0.39 to −0.25) in 1 study. SC ≤ 365 days vs ≤ 3 days did not lead to a change according to the authors.

1869
(2 observational studies)

⊕⊝⊝⊝
VERY LOW 2 3

RCT: Number of sickness absence periods per worker
Follow‐up: 6 months

SC ≤ 14 days led to no difference in the number of sickness absence periods compared to SC ≤ 7 days, but the authors did not report numerical data.

237,391
(1 RCT)

⊕⊕⊝⊝
LOW 1

CBA: Number of sickness absence periods per worker
Follow‐up: 1 year

SC ≤ 3 days vs SC 0 days led to an increase in 1 study (0.48 sickness absence periods lasting ≤ 3 days, 95% CI 0.33 to 0.63), and SC ≤ 365 days vs ≤ 3 days did not lead to a considerable difference in the number of sickness absence periods, but the authors did not report numerical data.

1869
(2 observational studies)

⊕⊝⊝⊝
VERY LOW 2 3

RCT: Average lost work time per 100 person‐years
Follow‐up: 6 months

SC ≤ 14 days vs SC ≤ 7 days led to an inferred increase in lost work time.

237,391
(1 RCT)

⊕⊝⊝⊝
LOW 1 4

CBA: Average lost work time per 100 person‐years
Follow‐up: 1 year

SC ≤ 3 days vs 0 days led to 0.54 days more lost work time (95% CI 0.47 to 0.61) in 1 study. SC ≤ 5 days vs SC ≤ 3 days led to 1.38 days (95% CI 1.16 to 1.60) more lost work time in absence periods of ≤ 3 and 0.1 days (95% CI could not be calculated) in absence periods of 4 to 16 days in 1 study. SC ≤ 50 days vs SC ≤ 3 days led to 0.65 days less lost work time in 1 study based on absence periods of 4 to 16 days. SC ≤ 365 days vs SC ≤ 3 days led to a decrease of −2.84 days in lost work time (95% CI −3.35 to −2.33) based on absence periods of > 16 days.

17,114
(4 observational studies)

⊕⊝⊝⊝
VERY LOW 2 5

RCT: Costs of sickness absence and physician certification

The cost of 1 day of sickness absence (SEK 296) was obtained using the average daily compensation paid by employers to employees. Given the cost of a physician appointment (SEK 445), the higher costs of sickness absence benefits (SEK 29,000,000) far outweighed the possible reduction in costs of fewer physician appointments (SEK 4,900,000) during 1 year.

237,391
(1 RCT)

⊕⊕⊝⊝
LOW 1

CBA: controlled before‐after study; CI: confidence interval; RCT: randomised controlled trial; SC: self‐certification, which means that a worker is allowed to take short periods (of a predetermined maximum length) of sick leave due to minor illnesses without obtaining an official document from a doctor (i.e. physician certification).

GRADE Working Group grades of evidence
High certainty: We are very confident that the true effect lies close to that of the estimate of the effect.
Moderate certainty: We are moderately confident in the effect estimate: the true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different.
Low certainty: Our confidence in the effect estimate is limited: the true effect may be substantially different from the estimate of the effect.
Very low certainty: We have very little confidence in the effect estimate: the true effect is likely to be substantially different from the estimate of effect.

1We downgraded the certainty of evidence by two levels, that is from high to moderate and then from moderate to low, due to risk of bias. The authors performed randomisation by date of birth, which is an inadequate randomisation method, and they did not blind participants or intervention providers.
2We downgraded the certainty of evidence by one level, that is from low to very low, due to risk of bias because the authors did not take critical confounders into account. Given the small number of included studies, we could not assess the possible influence of publication bias. We found no reason to upgrade the certainty of the evidence.
3We would have downgraded the certainty of evidence by one more level due to inconsistency because two studies produced opposing results, but we had already reached very low certainty.
4We downgraded the certainty of evidence by one level, that is from low to very low, due to indirectness because we inferred the conclusion about lost work time from two other outcomes.
5We would have downgraded the certainty of evidence by one more level due to inconsistency because results in studies with less self‐certification time showed an increase in lost work time, whereas two studies with much longer self‐certification showed a decrease in lost work time, but we had already reached very low certainty.

Background

Description of the condition

Sickness absence or sick leave can be defined as "absence from work that is attributed to sickness by the employee and accepted as such by the employer" (Whitaker 2001). 'Sick pay' refers to the continuation of payment of the employee’s salary (or part of it) by the employer during the sickness absence. A sickness benefit is usually paid from insurance after the employer’s obligation of sick pay has ceased (Spasova 2016). From the perspective of society and the employer, sickness absence has a large economic impact. The incidence of sickness absence and the methods that are used to calculate the costs vary among countries; however, a conservative estimate of the average cost of sickness absence to a nation is 2.5% of gross domestic product (GDP) (Eurofound 2010).

Definitions of short‐ and long‐term sickness absence vary among studies. On one hand, long‐term sickness absence has been defined as an absence exceeding 20 to 90 days or longer (Higgins 2012). On the other hand, the National Institute for Health and Care Excellence (NICE) guidance (UK) defines long‐term sickness absence as four or more weeks (Gabbay 2011; NICE 2009). A short sickness absence from work is usually a minor disturbance from the perspective of the workplace, with work often taken over by colleagues. For longer‐term sickness absence periods, replacements are needed that must be paid in addition to the payment of sickness benefit. It can be inferred that both short‐ and longer‐term sickness absence affect productivity and the economic health of companies as well as that of the country. In this Cochrane Review, we have focused on short‐term sickness absence, which is defined as an absence of less than four weeks, based on the NICE guidelines (NICE 2009).

Description of the intervention

An important procedure in the recognition of a need for sickness absence is the certification of illness or reduced work ability by a physician. This means that, in the case of sickness and reduced work ability, an employee needs a medical certificate to be absent from work. The certifying physician is often a general practitioner. It has been reported in Sweden, where self‐certification is common, that 9% of visits to general practitioners included sickness certification (Englund 2000). Internationally, there is variation in sickness certification practices. Some countries, such as the Netherlands, do not use any official sickness certification procedures, and employers are free to organise sick leave procedures jointly with their employees. In other countries, there can be a period of varying length at the beginning of the sickness absence during which no medical certificate is needed. Usually the employee notifies his or her supervisor when taken ill, a procedure known as self‐certification. The role of the supervisor may vary from merely registering the notification to actually assessing the situation before giving permission to stay at home without a medical certificate. The permitted duration of absence based on self‐certification usually ranges from one to seven days (NOSOSCO 2015; Wynne‐Jones 2008). As the self‐certification practices may vary not only among countries, but also between workplaces within a country, the effects are usually studied at the aggregate level of organisations, companies, municipalities, healthcare settings, or general populations.

How the intervention might work

Sickness absence and return to work may be associated with multiple factors at the levels of the individual, work and work environment, other areas of life, features of the social insurance system, and the larger societal context. Consequently, there are several pathways (practical, attitudinal, and motivational) at various levels (individual employee, the workplace, and (occupational) health care) that may mediate the effect of changing the period of self‐certification of sickness absence on short‐term sickness absence and associated costs, social climate, supervisor involvement, and workload or presenteeism (working while ill; Figure 1). In a Finnish survey (Hinkka 2018), the majority of participating physicians found that the insufficient availability of healthcare services in the public sector was one reason for prolonged sickness absences. The practice by which the worker has to make an appointment with the physician and the physician has to be available may also prolong sickness absence, while self‐certification practice could shorten the absence when access to health care is poor. These kinds of administrative factors may increase the duration of very short‐term sick leave. For example, if a physician certificate is required, the appointment with the physician may delay return to work due to physician availability, even if the employee felt healthy enough to return to work earlier. The physician is also likely to make a conservative assessment of the work ability of the worker to prevent presenteeism. A self assessment might therefore decrease the number of days absent from work, because without a medical certificate, the employee may be more likely to return to work as soon as she or he feels fit to work, as no restrictions are set by a medical certificate (Pesonen 2016).

Self‐certification can be interpreted by the employee as increased decision latitude (ability to make work‐related decisions and personal control over work‐related matters), while poor decision latitude at work has been associated with increased sickness absence (Melchior 2003; Michie 2003). It is also possible that employees may interpret self‐certification as an indication of the employer's trust, which can in turn result in a stronger commitment to work, decrease in sickness absence, and positive effect on social climate in the workplace (Pesonen 2016). Social climate can be defined as a shared, distinctive, and dynamic perception of social environment that can influence behaviour (Bennett 2010).

The requirement of a sickness certificate from a physician may be thought of as a means to control the use of sick leave because of the existence of a moral hazard. In economic terms, a moral hazard implies that individuals utilise sickness absence (or insurance) more than necessary to maximise their utility (Khan 2009). In fact, the moral hazard may apply especially to short sickness absence periods, because for longer periods it would be more evident that there is a medical cause for the absence. According to this logic, the requirement of a sickness certificate in the case of short‐term sickness absence would be a strong intervention to prevent the moral hazard, and changing to a self‐certification procedure would possibly lead to a moral hazard problem with an increase in short‐term sickness absence periods. On the other hand, it is possible that introducing or extending self‐certification will result in presenteeism.

An earlier investigation found that a self‐certification practice improved communication between employees and supervisors (Pesonen 2016); good communication between employees and supervisors can prevent or mitigate the possible moral hazard related to self‐certification (Nieuwenhuijsen 2004). The supervisors found that the practice of self‐certification was a useful tool in the management of well‐being at work. On the other hand, Pesonen 2016 also found that the practice of self‐certification increased supervisors' workload. However, self‐certification decreased the use of resources in occupational health care and permitted the shift of resources to preventive work. This suggests that if healthcare providers perform less sickness certification, resources that can be used elsewhere, for example for preventive services, will be made available.

Why it is important to do this review

For short periods of sickness absence in particular, physician certification is an expensive process due to the administrative procedures involved. In addition, physician certification is associated with considerable costs and uptake of resources that could be better used in other healthcare areas. It is also known that sickness certification practices vary significantly between physicians (Arrelöv 2005; Englund 2000; Kankaanpää 2014). Literature reviews have concluded that physicians report difficulties with the certification process (Letrilliart 2012; Wynne‐Jones 2010). However, as the role of general practitioners in sickness certification differs between countries, there may be variation regarding which aspects of the process are problematic (Winde 2012). Altogether, sickness certification involving a physician has been regarded as a burden to employees, the employer, the healthcare system, and society (Letrilliart 2012).

Sickness certification practices vary between countries, and self‐certification is not a common practice in all countries. It is unclear whether and how sickness absence is altered when the requirements of a sickness certificate change. Self‐certification will potentially decrease the total number of short‐term sick leave days because there will be less administrative delay with the frequently occurring shorter periods, and employees can return to work as soon as they feel well enough to work. However, it is likely that self‐certification will not influence the duration of long‐term sick leave because the medical condition will be more serious, and assessment and documentation by a physician will be a natural part of healthcare procedures.

A randomised controlled trial conducted in Sweden found that postponing the requirement for a physician’s certificate from day eight until day 15 increased the average duration of sickness absences by 6.6% (Hesselius 2005). A cost‐benefit analysis showed that costs of increased sickness duration exceeded the benefits from fewer medical appointments. In contrast, a Norwegian study by Mykletun 2014 showed that when the sickness certification entitlement was transferred from physicians to employees (self‐certification) for a period of one year, there was a significant decline in sickness absence. Recently, a Finnish case study of six companies indicated that changing from physician certification to a self‐certification system did not affect the total number of sick leave days (Pesonen 2016). However, short‐term absence days decreased slightly, and the researchers pointed out that there were other benefits, such as a more active role of the supervisor and a 20% to 40% decrease in physician consultations.

A literature review on rates of sickness certification suggested that the countries with the longest period of self‐certification (e.g. the UK and Sweden, with seven days) reported high overall rates of sickness certification when compared to countries with shorter self‐certification periods (e.g. Norway, with four days, and Switzerland, with three days) (Wynne‐Jones 2008). However, other factors such as the existence of waiting days (i.e. the first days of sickness absence without pay, or the length of the period of sick pay) may also affect sickness absence rates. Due to the uncertainty surrounding the benefits and costs of self‐certification, it was important to conduct a systematic review to combine the findings of existing studies. As far as we know, there are no systematic reviews on the effects of different sickness certification practices on sickness absence or related costs. Systematic reviews on sick leave and sickness certification practices are needed, as they can be used in preparation of evidence‐based guidelines for health care.

Objectives

To evaluate the effects of introducing, abolishing, or changing the period of self‐certification of sickness absence on:

  1. the total or average duration (number of sickness absence days) of short‐term sickness absence periods;

  2. the frequency of short‐term sickness absence periods;

  3. the associated costs (of sickness absence and (occupational) health care); and

  4. social climate, supervisor involvement, and workload or presenteeism (Figure 1).


Logic model of the intervention

Logic model of the intervention

Methods

Criteria for considering studies for this review

Types of studies

We included randomised controlled trials (RCTs) where individual employees were randomly assigned either to a group that continued with the current practice of sickness certification (by a physician or by the employee his or herself) or to a group that started a new practice of sickness certification. The change could be from physician certification to self‐certification (or vice versa) or to a longer or shorter period of self‐certification. Legal and practical constraints will make randomisation difficult at the individual level, but it is conceivable that these constraints could be overcome by using a cluster‐randomised design in which groups of workers or whole organisations are randomly assigned to the intervention or the control group, therefore we also included cluster‐RCTs.

Because of the difficulty of performing randomised trials evaluating this intervention, we also considered the following observational study designs for inclusion: controlled before‐after (CBA) studies (otherwise known as prospective cohort studies or quasi‐experimental studies) and interrupted time‐series (ITS) studies. Given the fluctuation in sick leave indicators over time, these study designs should be able to control for trends related to factors other than the intervention. Without such caution, it would be difficult to make inferences from the results of the studies.

Controlled before‐after studies are easier to perform ‐ considering that the intervention is carried out at the group level ‐ while maintaining reasonable validity. We defined CBA studies as prospective or retrospective studies in which measurements of the outcome were available both before and after the implementation of the intervention for both the intervention and control group, and in which the outcome was measured at the same moment in time for both groups.

Interrupted time‐series studies are studies with or without a control group in which the outcome has been measured at least three times before the intervention and at least three times after the intervention. The intervention is applied at a specific well‐defined moment in time and is supposed to have an immediate effect, a long‐term effect, or both. Because the outcome is measured several times before and after the intervention, it is possible to take time trends into account and thus make up for the lack of a control group (Ramsay 2003).

Types of participants

We included studies involving individual employees or insured workers. We also included studies in which participants were addressed at the aggregate level of organisations, companies, municipalities, healthcare settings, or general populations.

Types of interventions

We included studies evaluating the effects of introducing, abolishing, or changing the period of self‐certification of sickness absence. We included any sickness certification practice in which the employee could report sick for a certain number of days without physician certification or certification by any other healthcare professional. Self‐certification could be accepted for any disease or restricted to certain types of diseases.

We also included studies that combined self‐certification with an intervention related to supervisor role or practices, working conditions (e.g. flexible working conditions), or terms of sickness benefit (e.g. number of waiting days), etc. (i.e. multicomponent interventions).

Types of outcome measures

Primary outcomes

  1. The total or average duration (number of sickness absence days) of short‐term sickness absence periods.

  2. The total or average number of short‐term sickness absence periods.

If self‐certification was restricted to certain diseases, we also considered the outcomes only for those diseases.

We included any type of measurement of sickness absence, such as administrative data or self reported data.

We reported the results of economic evaluation studies related to introducing, abolishing, or changing the period of self‐certification of sickness absence. We evaluated costs from the perspective of society, the employer, and the employee. The cost‐related outcome measures were:

  1. the costs of short‐term sickness absence per employee (average within the organisation);

  2. the total cost of short‐term sickness absence;

  3. the costs of (occupational) health care; and

  4. changes in productivity.

We categorised the outcome measurements according to three follow‐up times: up to three months, between three and six months, and six months or longer.

Secondary outcomes

We also included studies measuring a change in the social climate, supervisor involvement, and workload or presenteeism, regardless of whether they reported any of the primary outcomes.

Search methods for identification of studies

Electronic searches

We conducted a systematic literature search to identify all potentially eligible published and unpublished studies. We adapted the search strategy developed for MEDLINE for use in the other electronic databases. We imposed no restriction on language of publication. We arranged for the translation of key sections of potentially eligible non‐English language papers or that such papers were fully assessed for inclusion by individuals proficient in the language of the publication as needed.

We searched the following electronic databases from inception to present for identifying potential studies.

  1. Cochrane Central Register of Controlled Trials (CENTRAL) in the Cochrane Library (Appendix 1, Issue 4 of 12, April 2018).

  2. MEDLINE Ovid (Appendix 2, 20 April, 2018).

  3. SCOPUS (Appendix 3, 23 May, 2018).

  4. PsycINFO Ovid (Appendix 4, 23 May, 2018).

  5. EBM Reviews Ovid (Appendix 5, 14 June, 2018).

  6. CINAHL EBSCOhost (Cumulative Index to Nursing and Allied Health Literature) (Appendix 6, 30 May, 2018).

  7. EconLit ProQuest and EconPapers (Appendix 7, 14 June, 2018).

  8. EBSCO Business Source Elite (EBSCOhost) (Appendix 8, 30, May 2018).

  9. NIOSHTIC, NIOSHTIC‐2, HSELINE, and CISDOC (OSH‐UPDATE) (Appendix 9, 30 May, 2018).

We also searched for unpublished trials in the US National Institutes of Health Ongoing Trials Register ClinicalTrials.gov (www.clinicaltrials.gov/) on 14 June, 2018 and the World Health Organization International Clinical Trials Registry Platform (WHO ICTRP) (www.who.int/ictrp/en/) also on 14 June, 2018. We utilised Google Scholar for exploratory searches.

Searching other resources

We contacted experts in the field to identify additional unpublished materials. We also searched websites of social security organisations such as the International Social Security Association (ISSA) for potentially eligible studies. We checked reference lists of the included studies for additional references.

Data collection and analysis

Selection of studies

We used the study screening tool Covidence to conduct the selection of eligible studies in two stages (Covidence). First, pairs of review authors (JK, JHV, JHR, JIH, LJV) independently screened titles and abstracts of all potentially relevant studies identified by our systematic search. The same authors coded them as 'include' (eligible or potentially eligible/unclear) or 'exclude'. At this stage we excluded all references that clearly did not fulfil our inclusion criteria or that did fulfil our exclusion criteria. Any differences of opinion regarding references coded 'include' were discussed until consensus was reached. At the second stage, we retrieved the full‐text study reports or publications, and two review authors (JK and JIH) independently assessed the full‐texts and identified studies for inclusion in the review, and recorded reasons for exclusion of the ineligible studies in the 'Characteristics of excluded studies' table. Any disagreements were resolved through discussion or by consulting a third review author (JHR) if necessary. We identified and excluded duplicates and collated multiple reports of the same study so that each study, rather than each report, is the unit of interest in the review. We recorded the selection process in sufficient detail to complete a PRISMA study flow diagram (see Figure 2).


PRISMA study flow diagram.

PRISMA study flow diagram.

Had our systematic searches identified studies conducted by authors of this review, review authors who were not involved with the study would have made decisions involving inclusion and exclusion in order to avoid conflicts of interest.

When there was insufficient information about a study to reach a decision on eligibility, we sought to obtain further information from the authors.

We will rerun our systematic searches for trials every two years to enable updating of the review accordingly.

Data extraction and management

We used a data collection form that had been piloted on at least one study in the review to extract study characteristics and outcome data. Two review authors (JK and JIH) extracted the following study characteristics from the included studies.

  1. Methods: study design, total duration of study, study location, study setting, withdrawals, and date of study.

  2. Participants: N, mean age or age range, sex/gender distribution, occupation, type of work and branch of industry, and inclusion and exclusion criteria.

  3. Interventions: description of intervention, comparison, duration, intensity, content of both intervention and control condition, and co‐interventions.

  4. Outcomes: description of primary and secondary outcomes specified and collected, and time points reported.

  5. Notes: funding for trial and notable conflicts of interest of trial authors.

Two review authors (JK and JIH) independently extracted outcome data from the included studies. All data were reported in a useable way. Any disagreements were resolved by consensus or by involving a third review author (JHR). One review author (JK) transferred data into the Review Manager 5 file (RevMan 2014). We double‐checked that data were entered correctly by comparing the data presented in the systematic review with that in the study reports. A second review author (JIH) spot‐checked study characteristics for accuracy against the trial report. If in future updates of this review we should decide to include studies published in one or more languages in which our author team is not proficient, we will arrange for a native speaker or someone sufficiently qualified in each foreign language to fill in a data extraction form for us.

Assessment of risk of bias in included studies

Risk of bias in randomised controlled trials

Two review authors (JK and JHR) independently assessed risk of bias for each study using the Cochrane 'Risk of bias' assessment tool criteria outlined in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011). Any disagreements were resolved by discussion or by involving another review author (JHV or JIH) if necessary. We assessed risk of bias according to the following domains.

  1. Random sequence generation (selection bias).

  2. Allocation concealment (selection bias).

  3. Blinding of participants and personnel (performance bias).

  4. Blinding of outcome assessment (detection bias).

  5. Incomplete outcome data (attrition bias).

  6. Selective outcome reporting.

  7. Other bias.

We graded each potential source of bias as high, low, or unclear, and provided a quote from the study report together with a justification for our judgement in the 'Risk of bias' table. We summarised the 'Risk of bias' judgements across different studies for each of the domains listed. We considered blinding separately for self reported or administrative data of sickness absence: for self reported data, we considered the risk of bias due to blinding to be high, and for administrative data we considered it to be low. Where information on risk of bias related to unpublished data or correspondence with a trialist, we noted this in the 'Risk of bias' table. We contacted study authors in the case of insufficient information regarding risk of bias.

Risk of bias in controlled before‐after studies

We used the Risk Of Bias In Non‐randomised Studies ‐ of Interventions (ROBINS‐I) tool for assessing risk of bias in CBA studies (Sterne 2016). The seven domains of bias addressed in the ROBINS‐I assessment tool are as follows.

  1. Confounding.

  2. Selection bias.

  3. Bias in classification of interventions.

  4. Bias due to deviations from intended interventions.

  5. Bias due to missing data.

  6. Bias in measurement of outcomes.

  7. Bias in selection of the reported results.

We graded each potential source of bias as critical, serious, moderate, low, or no information. We summarised the risk of bias judgements across different studies for each of the domains listed. Our target trial against which we assessed the risk of bias was a trial in which participants that report sick were assigned to physician certification (or a shorter period of self‐certification) and self‐certification (or a longer period of self‐certification) at the start of sick leave. We considered age, gender, and type of job (blue versus white collar) as potential confounders for which studies would have been expected to have adjusted in the design or in the analysis because these variables are related to a longer sickness absence or higher frequency of absence. We assessed waiting days or specific supervisor responsibility for sickness absence as co‐interventions that could differ between intervention and control group and have an impact on the primary outcome. We first used the signalling questions as prescribed in the ROBINS‐I tool and then assessed the risk of bias if these questions indicated a potential risk of bias.

Risk of bias in interrupted time‐series studies

If we include ITS studies in future updates of this review, we will use the risk of bias criteria developed by the Cochrane Effective Practice and Organisation of Care Group (EPOC), which entails assessing the risk of bias in ITS studies against the following criteria.

  1. Was the intervention independent of other changes?

  2. Was the shape of the intervention effect prespecified?

  3. Was the intervention unlikely to affect data collection?

  4. Was knowledge of the allocated interventions adequately prevented during the study?

  5. Were incomplete outcome data adequately addressed?

  6. Was the study free from selective outcome reporting?

  7. Was the study free from other risks of bias?

We will judge the risk of bias of ITS studies in all of the above domains to be high, low, or unclear. When one or more domains is judged to be at high risk of bias, the ITS study will be considered to be at high risk of bias.

We considered randomisation (confounding, selection), allocation concealment, and blinded outcome assessment to be key domains. We judged a study to have a high risk of bias overall when one or more key domains had a high risk of bias. Conversely, we judged a study to have a low risk of bias when all key domains had a low risk of bias and none of the other domains had a high risk of bias.

When considering treatment effects, we took into account the risk of bias for the studies that contributed to that outcome.

Assessment of bias in conducting the systematic review

We conducted the review according to the published protocol, Kausto 2018, and have reported any deviations from it in the Differences between protocol and review section of the review.

Measures of treatment effect

For RCTs and CBA studies, we calculated the results of each trial as point estimates, meaning means and standard deviations (SD) because all studies reported relevant outcome data using continuous outcomes. If in future updates of this review we identify studies reporting only effect estimates and their 95% confidence intervals or standard errors, we will enter these data into Review Manager 5 using the generic inverse‐variance method (RevMan 2014).

As all results were reported using unambiguous continuous outcomes (number of sickness absence days, number of sickness absence periods, or work time lost due to sickness absence) with the same direction (less is better), there was no need to reverse any scales. When the results could not be plotted, we have described them in the 'Characteristics of included studies' table.

If we include ITS studies in future updates of this review, we will extract data from the original papers and re‐analyse them according to recommended methods for analysis of ITS designs for inclusion in systematic reviews and also as recommended for evaluation of law studies (Viscusi 2005). These methods utilise a segmented time‐series regression analysis to estimate the effect of an intervention while taking into account secular time trends and any autocorrelation between individual observations. If an included ITS study uses a control group, we will use the difference in rates between the intervention and the control group as the outcome. For each study, we will fit a first‐order autoregressive time‐series model to the data using a modification of the parameterisation of Ramsay 2003. Details of the model specification are as follows: Y = β0 + β1time + β2 (time‐p) I (time > p) + β3 I (time > p) + E, E ˜ N (0, s2).

For time = 1,...,T, where p is the time of the start of the intervention, I (time ≥ p) is a function which takes the value 1 if time is p or later and zero otherwise, and where the errors E are assumed to follow a first‐order autoregressive process (AR1). The β‐parameters have the following interpretation: β1 is the pre‐intervention slope. β2 is the difference between post‐ and pre‐intervention slopes. β3 is the change in level at the beginning of the intervention period, meaning that it is the difference between the observed level at the first intervention time point and that predicted by the pre‐intervention time trend.

We will standardise the data of ITS studies to obtain effect sizes by dividing the outcome and standard error by the pre‐intervention SD as recommended by Ramsay 2003.

We will thus have two separate outcomes for an ITS study: the short‐term change in the level of the outcome due to the intervention, which can be interpreted as an additive effect, and the long‐term change in the trend in time or change of slope indicating an increasing effect of the intervention.

We had two primary outcomes: the mean number of short‐term sickness absence periods (< 30 days) and the mean duration of short‐term sickness absence periods. The number of short‐term periods is a rate because one person can have several short‐term sickness periods per year. A rate can also be analysed as continuous data. Because in some of the included studies the baseline rates differed between the intervention and the control group, we have used change values for the mean rate per person‐year and calculated the intervention effect as the mean difference in the change values between the intervention and the control group: mean difference (MD)change.

For the studies by Taylor 1969, Torsvik 2014, and Saksvik 2001, we calculated the duration of short‐term sickness absence periods from the available data. For the duration of the periods we took the reported length that was nearest to the length of the self‐certification period. If the self‐certification period was up to three days, we extracted data on periods lasting up to three days. We extracted these data on the length of periods close to the length of the self‐certification period because it is unlikely that self‐certification will influence the length of a sickness period after a physician has certified the sickness absence.

The duration of short‐term periods, in which we are interested, is the average duration of a period, calculated as the total of days lost due to short‐term absence divided by the number of short‐term absence periods. However, studies often reported “a percentage of work time lost of total work time”, which is equal to the average lost work time per worker. An illustrative example would be as follows. If 100 workers should have worked 239 days in a year, and short‐term absence periods of up to three days would have accumulated a total lost time of 239 days, this would be reported as 1% lost work time (= 239 lost days/(100 workers*239 workdays)*100). The changes in average lost work time for a specific duration of absence can thus be due to either a change in the number of periods, a change in the average duration of the periods, or both. For the studies that reported percentages, we recalculated the average percentage in lost workdays because this is more intuitive. For this calculation we estimated that there would be 239 workdays in a year in Norway (first including 22 workdays per month during 12 months and then excluding 25 days of holiday). Because one worker may have more than one short sickness absence period during a given study, the average duration of an absence period lasting, for example, up to three days can be longer than three days. For the studies that measured average lost work time, the baseline values were often different in the intervention and control groups, therefore we calculated the change in the outcome from before the intervention to after the intervention for the intervention and control groups, and used the difference in these change values as the effect of the intervention: MDchange.

Unit of analysis issues

If in future updates of this review we include studies that employ a cluster‐randomised design and that report sufficient data to be included in the meta‐analysis but that do not make an allowance for the design effect, we will calculate the design effect based on a large assumed intracluster correlation of 0.10. We base this assumption of 0.10 as being a realistic estimate by analogy to studies about implementation research. We will follow the methods described in Section 16.3.6 of the Cochrane Handbook for Systematic Reviews of Interventions for the calculations (Higgins 2011).

If several active interventions have been compared with no intervention, we will divide the participants in the no‐intervention control group by the number of interventions, as recommended in the Cochrane Handbook for Systematic Reviews of Interventions for the purposes of meta‐analysis (Higgins 2011).

Dealing with missing data

We contacted investigators of all five included studies to verify key study characteristics and to obtain missing numerical outcome data where possible (e.g. when results were reported in figures only). If in future updates of this review we include studies for which we are not able to obtain this information, and we think that the missing data introduce serious bias, we will explore the impact of including such studies in the overall assessment of results by a sensitivity analysis.

If numerical outcome data such as SDs or correlation coefficients were missing and could not be obtained from the study authors, we calculated this information from other available statistics such as P values according to the methods in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011).

Assessment of heterogeneity

We first assessed clinical homogeneity based on the similarity of the intervention, control condition, outcome, population, and follow‐up time. We considered all types of participants to be similar. We considered any introduction, abolishment, increase, or decrease in the self‐certification period to be similar. We considered all sick leave outcomes as similar (i.e. no restrictions due to diagnosis), although they were measured and reported differently.

Provided sufficient data are included in future updates of this review, we will also test for statistical heterogeneity by means of the Chi² test as implemented in the forest plots in Review Manager 5 (RevMan 2014). We will use a significance level of P < 0.10 to indicate if there is a problem with heterogeneity. In addition, we will quantify the degree of heterogeneity using the I² statistic (where I² > 50% indicates a moderate degree of heterogeneity and I² > 75% indicates a high degree of heterogeneity). When we identify ≥ 75% heterogeneity between studies we will refrain from pooling their results for meta‐analysis.

Assessment of reporting biases

We reduced the effects of reporting bias by including studies and not articles. We prevented location bias by searching multiple databases. We prevented language bias by not using any language restrictions. We checked for outcome reporting bias as part of the risk of bias assessment.

Data synthesis

We have presented results separately for RCTs and CBA studies.

Provided sufficient data are included in future updates of this review, we will pool data from studies judged to be clinically homogeneous using Review Manager 5 software (RevMan 2014). If possible, we will combine studies using MDs. If different outcomes do not permit pooling, then we will use standardised mean differences (SMDs). To make the SMDs more readily interpretable for clinicians, we will then recalculate the pooled SMD into an MD by multiplying the SMD by the median SD taken from the included studies using the preferred scale in question. We will pool results from studies with different study designs if the direction and the magnitude of the studies are considered similar.

We will use the generic inverse‐variance method as implemented in Review Manager 5 to combine hazard ratios and effect sizes obtained from ITS studies (RevMan 2014).

Given the type of interventions and the conditions under which trials would have been conducted, we expected statistical heterogeneity, therefore we planned to use a random‐effects model for meta‐analysis. If heterogeneity between studies is low, the results will be similar to those from a fixed‐effect model. All estimates will include a 95% confidence interval.

We expected that not all included studies would contain an economic evaluation.

'Summary of findings' table

We have presented a 'Summary of findings' table using all primary and secondary outcomes: mean duration of short‐term sickness absence periods, mean number of short‐term sickness absence periods, and average lost work time per 100 person‐years for our main comparison between longer self‐certification and shorter self‐certification for reducing sickness absence in workers.

We used the five GRADE considerations (study limitations, consistency of effect, imprecision, indirectness, and publication bias) to assess the quality of a body of evidence as it relates to the studies which contributed data to the prespecified outcomes. We used the methods and recommendations in Chapters 8 and 12 of the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2017; Schünemann 2017). We intended to use GRADEpro GDT software (GRADEpro GDT 2015) but there were no studies that could be combined and we reported the results in a narrative summary of findings table. We justified all decisions to down‐ or upgrade the quality of evidence using footnotes.

Subgroup analysis and investigation of heterogeneity

Provided sufficient data are available in future updates of this review, we will compare the effects of interventions on the following three variables in subgroup analyses.

  1. The length of increase or decrease in the self‐certification period, where we will compare the effects of studies with participants that have up to seven calendar days versus more than seven calendar days of self‐certification.

  2. The existence of so‐called waiting days, i.e. days at the beginning of sickness absence when sick pay is not payable, where we will compare the effects of studies with participants that do not have waiting days versus studies with any number of waiting days.

  3. The existence of flexible working conditions such that we will compare studies conducted with participants who have flexible working conditions versus those without flexible working conditions.

We will use the Chi² test to test for subgroup interactions in Review Manager 5 (RevMan 2014).

Sensitivity analysis

Provided sufficient data are available in future updates of this review, we will conduct sensitivity analyses to test the robustness of our meta‐analysis results by leaving out studies judged to be at high risk of bias. We will also conduct sensitivity analyses for possible assumptions made for missing data or analyses during the review process.

Reaching conclusions

We will base our conclusions only on findings from the quantitative or narrative syntheses of the studies included in this review. We will avoid making recommendations for practice based on anything other than the evidence. We will suggest priorities for future research and outline what the remaining uncertainties are in the area.

Results

Description of studies

Results of the search

We identified a total of 6573 references from CENTRAL (50), MEDLINE (918), SCOPUS (1639), PsycINFO (228), EBM Reviews (43), CINAHL (620), EconLit (710), EBSCO Business Source Elite (1794), EconPapers (71), OSH‐UPDATE (417), ClinicalTrials.gov (56), and the WHO ICTRP (27). We identified no references from reference lists of potentially included studies, contact with experts, and searching the ISSA website. After excluding 482 duplicates, we screened the titles and abstracts of 6091 references for potential inclusion in the review. We obtained the full‐texts of 28 articles on 17 studies, of which we excluded 21 articles because they did not meet our inclusion criteria for the following reasons: eight articles (study design), seven (intervention), four (duplicates), and two (study setting) (see Characteristics of excluded studies). We included five studies described in five articles in the review. A PRISMA study flow diagram depicting the results of the search and the process of screening and selecting studies is shown in Figure 2.

Included studies

Study designs

We found only one RCT, by Hesselius 2005. The other four included studies used a mixture of study designs that fit our definition of CBA studies (Fleten 2009; Saksvik 2001; Taylor 1969; Torsvik 2014).

Settings

Interventions were carried out among municipality or company employees or insurance claimants in municipalities. Of the five included studies, three were from Norway (Fleten 2009; Saksvik 2001; Torsvik 2014), one was from Sweden (Hesselius 2005), and one was from the UK (Taylor 1969).

Participants

Participants were employees or insurance claimants studied at the aggregate level.

Interventions

In Taylor 1969, the intervention was self‐certification introduced to employees for absence periods lasting up to three working days. Upon return to work, employees had to complete a sickness report for the personnel record office. The comparator was physician certification of sickness absence. In the other four studies, the intervention was prolonging the period of self‐certification of sickness absence. The comparison was between a longer and a shorter period of self certified sickness absence. In the study by Saksvik 2001, municipality employees were entitled to have one to three self administered sick leave days four times per year at baseline, while the intervention group was entitled to have one to five self administered sick leave days four times per year. In the study by Hesselius 2005, the intervention group was allowed to receive sickness benefits for two weeks without showing a doctor’s certificate, while the control group continued the practice‐as‐usual of being entitled to the benefits without showing a doctor’s certificate for one week. In the study by Fleten 2009, the intervention consisted of prolonging the period of self‐certification of sickness absence up to 50 days per year, divided into one to 10 periods with a structured workplace follow‐up. In the study by Torsvik 2014, the comparison was between self‐certification up to one year (intervention) and practice‐as‐usual, that is a medical certificate was needed either on the third or the eighth day of sickness absence.

Outcomes

The outcomes in each of the included studies were differently measured. Taylor 1969 reported percentage of change in total sickness absence from the year before the experiment to the year following the experiment, proportion of sickness absence periods by duration before and after the experiment, and number of sickness absence periods by duration after the experiment for the intervention and control group. The authors of Saksvik 2001 reported percentages of time lost of total possible work time for self reported sickness absences of one to three days' duration at three time points for both the intervention and control groups. However, the authors did not calculate changes between baseline and the end of follow‐up. The authors of Hesselius 2005 reported the length of sickness absence periods for the intervention and control groups by survival analysis (return‐to‐work curves). They also reported risk ratios between the intervention and control groups at two time points. In Fleten 2009, the authors reported mean durations of sickness absence periods of 1 to 3 days', 4 to 7 days', and 4 to 16 days' duration at several time points before and after the intervention. They reported control group results only partly for sickness absence periods of one to three days. In Torsvik 2014, the authors reported the average absence percentage of contracted workdays and the average length of sickness absence periods for the intervention and control groups before and after the experiment. All included studies had a follow‐up time of longer than six months.

Excluded studies

We excluded a total of 17 studies reported in 21 full‐text articles. Four articles were duplicates of Hesselius 2005, Torsvik 2014, Preece 2006, and Saksvik 2001. The main reasons for excluding studies were as follows.

  1. Study design (Carne 1969; Felder 2008; Gjesdal 2005; Hauge 2017; Herrmann 2015; Ihlebaek 2006; Money 2013; Royneland 2002).

  2. Intervention (De Paola 2014; Kaufmann 2010; Pertold 2018; Pettersson‐Lidbom 2013; Pollak 2017; Schlotzhauer 1985; Voss 2001).

  3. Study setting (Oyeflaten 2011; Preece 2006).

Risk of bias in included studies

Two review authors (JK and JIH) independently assessed the risk of bias using the Cochrane 'Risk of bias' tool criteria outlined in the Cochrane Handbook for Systematic Reviews of Interventions for the one included RCT (Higgins 2011). We used the ROBINS‐I tool to assess risk of bias for the four included CBA studies (Sterne 2016). The results are summarised in Figure 3, which shows the review authors' judgements about each risk of bias item for each included study, and in Figure 4, which shows the review authors' judgements about each risk of bias item presented as percentages across all included studies.


Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.


Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Allocation

We judged the single included RCT by Hesselius 2005 to have a high risk of selection bias because the authors randomised participants based on their date of birth, which does not guarantee true randomisation, and because they did not report if or how allocation was concealed between randomisation and the start of the study.

There was no information regarding selection bias in Fleten 2009 and Taylor 1969, therefore we judged the risk of allocation bias to be unclear. In Fleten 2009, the selection of participants was based on municipalities and not on participant attributes. The authors also did not report any baseline descriptive information regarding the intervention and control groups. In Taylor 1969, the intervention group comprised all manual labour workers from an oil company, and the control group comprised all staff members of the same company. The authors did not report any baseline descriptive information regarding the intervention and control groups. We judged Saksvik 2001 and Torsvik 2014 to be at low risk of selection bias. In Saksvik 2001, employment in a certain district of a municipality was the selection method for both intervention and control groups. In Torsvik 2014, participants were allocated to intervention and control groups based on the municipalities in which they were employed.

Blinding

We judged the Hesselius 2005 RCT to have a high risk of performance bias because the participants were not blinded, and a low risk of detection bias because the authors obtained outcome data from a register.

Incomplete outcome data

We judged the Hesselius 2005 RCT to have an unclear risk of attrition bias because the authors did not provide any information on the completeness of outcome data.

Selective reporting

We judged the Hesselius 2005 RCT to have an unclear risk of reporting bias because the authors did not report a plan for their analyses, and they reported their findings based on total incidence and prevalence.

In the CBA studies by Taylor 1969, Fleten 2009, and Torsvik 2014, there was no information on selective reporting (no protocol or description of methods), thus we judged reporting bias to be unclear. We judged the Saksvik 2001 CBA study to have a low risk of reporting bias because the authors carried out and reported all planned analyses.

Other potential sources of bias

We judged the Hesselius 2005 RCT to have a low risk of other bias because we found no evidence of other major issues that could have introduced bias.

No studies reported waiting days or specific supervisor responsibility for sickness absence as co‐interventions.

Additional sources of bias according to ROBINS‐I items
Bias due to confounding

We judged three of the four CBA studies to be at serious risk of bias due to confounding (Fleten 2009; Saksvik 2001; Taylor 1969). Fleten 2009 only conducted a t‐test and did not include any confounders in their analyses. Saksvik 2001 used multivariate analysis of variance (MANOVA) to compare means but did not include any confounders other than age in the models. Most importantly, the authors did not adjust for sex and job type. They did not provide information on co‐interventions. Taylor 1969 considered only age in his analyses. We judged the fourth CBA study by Torsvik 2014 to be at moderate risk of bias due to confounding because the authors used a balanced panel of municipalities (Mandal versus similar municipalities) based on size and economic variables. However, the authors did not report whether they had included confounding variables in their analyses.

Bias due to missing data

In three of the four CBA studies (Fleten 2009; Saksvik 2001; Taylor 1969), there was no information to base a judgement on bias due to missing data, therefore we judged the risk of bias for this item to be unclear. We judged Torsvik 2014 to have a low risk of bias due to missing data because the authors obtained outcome data for the intervention and control groups from the same national register.

Bias in classification of interventions

We judged all four CBA studies to have a low risk of bias in classification of interventions (Fleten 2009; Saksvik 2001; Taylor 1969; Torsvik 2014). Allocation to either the intervention or the control group was based on employment in a certain municipality or in a certain district of a municipality or occupational status.

Bias due to deviations from intended interventions

We judged three CBA studies to be at low risk of bias due to deviations from intended interventions as there was no reason to believe that the intervention had changed over the follow‐up period (Saksvik 2001; Taylor 1969; Torsvik 2014). In Fleten 2009 there was not enough information to base a judgement on deviations from intended interventions, therefore we judged the risk of bias for this item to be unclear.

Bias in measurement of outcomes

We judged Saksvik 2001, Taylor 1969, and Torsvik 2014 to be at low risk of bias in measurement of outcomes as the authors had obtained outcome data from registers. In Fleten 2009 no information was provided to base a judgement because the authors collected outcome data from the control group only when sickness absence lasted longer than three days, therefore we judged the risk of bias in measurement of outcomes to be unclear.

Effects of interventions

See: Summary of findings for the main comparison Longer self‐certification compared to shorter self‐certification for reducing sickness absence in workers

1. Longer self‐certification compared to shorter self‐certification

1.1 The total or average duration (number of sickness absence days) of short‐term sickness absence periods

1.1.1 Evidence from RCTs

The RCT by Hesselius 2005 compared prolonging the period of self‐certification from one week to two weeks in two municipalities. The authors presented return‐to‐work curves from survival analysis. Following the intervention, the average duration of sickness absence periods lasting up to 29 days was 8.91 days (SD 14.6) in the intervention group and 8.24 days (SD 13.9) in the control group (data presented in Hesselius 2009). Based on the reported data, we calculated a mean difference (MD)change between intervention and control group in duration of absence periods lasting less than 29 days. The result shows self‐certification producing a higher mean duration of sickness absence, thus favouring physician certification after one week (MDchange 0.67 days/period, 95% confidence interval (CI) 0.55 to 0.79; Analysis 1.1).

1.1.2 Evidence from CBA studies

We identified one CBA study that compared duration of sickness absence periods after the introduction of self‐certification for a maximum of three days to duration of sickness absence periods before the introduction of self‐certification (Taylor 1969). Based on the reported data, we calculated an MD in the change from before to after intervention between intervention and control groups in the duration of sickness absence periods lasting up to three days. The result shows that self‐certification produced a lower mean duration of sickness absence, thus favouring self‐certification (MDchange −0.32 days/period, 95% CI −0.39 to −0.25; Analysis 1.1).

The CBA study by Torsvik 2014 compared prolonging the self‐certification period from three days to up to one year (365 days). The authors did not provide numerical values for the length of the absence periods, but wrote that there was no change in the mean duration of sickness absence periods.

1.2 The total or average number of short‐term sickness absence periods

1.2.1 Evidence from RCTs

In the RCT by Hesselius 2005, a self‐certification period of ≤ 14 days led to no difference in number of sickness absence periods compared to a self‐certification period of ≤ 7 days, but the authors did not report numerical data.

1.2.2 Evidence from CBA studies

Self‐certification produced a higher mean number of sickness absence periods, thus favouring physician certification (MDchange 0.48 periods, 95% CI 0.33 to 0.63; Analysis 1.2) in one older study (Taylor 1969). In order to estimate standard errors (SEs) for the work by Taylor 1969, we applied a distribution for the number of one‐ to five‐day sickness absence periods per person taken from the Finnish Helsinki Health Study conducted in 2000‐2002 (Lahelma 2013). We used the following percentages for the number of periods: zero periods 45%; one period 25%; two periods 13%; three periods 10%; four periods 5%; and five periods 2%. This enabled us to calculate the SD for the MDchange between intervention and control groups as: √((((0.25*N periods*(1 − mean N periods/worker)^2) + (0.13*N periods*(2 − mean N periods/worker)^2) + (0.10*N periods)*(3 − mean N periods)^2) + (0.05*N periods*(4 − mean N periods)^2) + (0.02*N periods*(5 − mean N periods)))/(N − 1))).

The authors of the Torsvik 2014 CBA study did not provide numerical values for the number of absence periods, but wrote that there was no change in the mean number of sickness absence periods in the intervention group.

1.3 Lost work time due to sickness absence periods per 100 person‐years

1.3.1 Evidence from RCTs

Because there was no difference in number of sickness absence periods between intervention and control groups in the Hesselius 2005 RCT, longer sickness absence periods will have led to an increase in lost work time in the intervention group, thus favouring physician certification.

1.3.2 Evidence from CBA studies

For the CBA study by Saksvik 2001, we calculated first SE and then the SD for the mean change in sickness absence periods of one to three days using the 95% CI from the other Norwegian CBA study by Fleten 2009 (Table 1: 95% CI 1.78 to 1.82). We thus calculated SE as: (1.82−1.78)/1.96, and SD as: SE*√N.

Based on the data reported in Saksvik 2001 and Taylor 1969, we were able to calculate MDs between change in intervention and control groups in lost work time due to sickness absence periods shorter than three days. In both cases, self‐certification resulted in more work time lost due to sickness absence periods lasting less than three days, thus favouring physician certification (Saksvik 2001: MDchange 1.38, 95% CI 1.16 to 1.60; and Taylor 1969: MDchange 0.54, 95% CI 0.47 to 0.61; Analysis 1.3). In Saksvik 2001, the MDchange for absence periods of 4 to 16 days was 0.1 days (95% CI could not be calculated).

The CBA study by Fleten 2009 compared the effects of prolonging the period of self‐certification from one to three days up to 50 days per year divided into one to 10 periods per year. For this study, we calculated SDs based on available data in the report as: SE*√N. Following the intervention, average lost work time due to absence periods lasting between four to 16 days decreased from 8.47 days to 7.82 days in the intervention group; the duration remained stable in the control group, but more detailed information on this was not provided. The change in lost work time was −0.65 days (when change in the control group was assumed to be 0 days), thus favouring self‐certification. This effect may be attributable to a reduction in the number of sickness absence periods or to a reduction in their average length.

In the CBA study by Torsvik 2014, the authors compared self‐certification up to one year and practice‐as‐usual (a medical certificate was needed either on the third or the eighth day of sickness absence). The authors presented the absenteeism data as mean per cent of sickness absence of all contracted working days per year. They included only sickness absence periods lasting 16 days or more in their analyses. From the percentages of lost total possible work time provided, we calculated an MD between change in the intervention and control groups in lost work time due to sickness periods longer than 16 days. We calculated SDs based on the SE and number of participants as reported by the authors as: SE*√N. The result shows self‐certification resulting in less work time lost due to sickness absence periods longer than 16 days, thus favouring self‐certification (MDchange −2.84 days, 95% CI −3.35 to −2.33; Analysis 1.3).

1.4 Cost of sickness absence

1.4.1 Evidence from RCTs

The authors of Hesselius 2005 valued one day of sickness absence by using the average daily compensation (SEK 296) paid by employers to employees. At the time of conducting the intervention in 1988 this covered 90% to 100% of wages. In the one‐week self‐certification group, 20.6% of participants had sickness absences longer than seven days, whereas in the two‐week self‐certification group 11.6% had sickness absences longer than 14 days. The increase in the length of the self‐certification period therefore led to a reduction in physician certifications of nine percentage points. The authors presented the cost of a physician's appointment as SEK 445. They calculated that the higher costs of sickness absence benefits (SEK 29,000,000) far outweighed the possible reduction in costs of fewer physician appointments in the Gothenburg area (SEK 4,900,000).

1.4.2 Evidence from CBA studies

We found no CBA studies using this outcome measure.

Discussion

Summary of main results

We included five studies (one RCT and four CBA studies) evaluating the effects of introduction of or a change in the length of self‐certification of sickness absence. One study from the 1960s evaluated the effect of introducing self‐certification, and the other four, later, studies evaluated the effect of prolonging the self‐certification period. The included studies measured the effects of the intervention on the number of sickness absence periods, the number of sickness absence days per sickness absence period, or on lost work time due to sickness absence periods. The results were inconsistent. See summary of findings Table for the main comparison for an overview of the results.

Effects on average duration of sickness absence periods

There is low‐certainty evidence from one RCT by Hesselius 2005 showing that extending the period of self‐certification from one week to two weeks increased the mean duration of sickness absence. There is very low‐certainty evidence from one old CBA study by Taylor 1969 showing that the introduction of self‐certification for a maximum of three days reduced the mean duration of sickness absence. There is very low‐certainty evidence from one CBA study by Torsvik 2014 showing that extending the self‐certification period from one to three days up to one year did not lead to a change in the mean duration of sickness absence. The authors of Torsvik 2014 did not report data to support this finding.

Effects on number of sickness absence periods per worker

There is low‐certainty evidence from one RCT by Hesselius 2005 that extending the period of self‐certification from one week to two weeks resulted in no difference in number of sickness absence periods. Unfortunately, the authors did not report data to support this finding. There is very low‐certainty evidence from one old CBA study by Taylor 1969 showing that the introduction of self‐certification for a maximum of three days increased the mean number of sickness absence periods. There is very low‐certainty evidence from another CBA study by Torsvik 2014 showing that extending the period of self‐certification from three days to up to a year did not change the number of sickness absence periods. The authors of Torsvik 2014 did not report data to support this finding.

Effects on average lost work time per 100 person‐years

There is low‐certainty evidence from one RCT by Hesselius 2005 showing that extending the period of self‐certification from one week to two weeks resulted in an inferred increase in lost work time. There is very low‐certainty evidence from two CBA studies by Saksvik 2001 and Taylor 1969 from different decades with very different data that could not be pooled, which showed that extending the period of self‐certification (from zero days to three days in Taylor 1969 and from three days to five days in Saksvik 2001) increased the amount of work time lost due to sickness absence periods lasting less than three days. There is very low‐certainty evidence from two CBA studies by Fleten 2009 and Torsvik 2014 showing that extending the period of self‐certification (from between one to three days up to 50 days per year divided into one to 10 periods per year in Fleten 2009, and from between three to eight days up to one year in Torsvik 2014) reduced the amount of work time lost due to sickness absence periods lasting four to 16 days and 16 days or longer, respectively.

Costs of sickness absence and physician certification

There is low‐certainty evidence from one RCT by Hesselius 2005 showing that the costs of sickness absence benefits resulting from a longer period of self‐certification were about six times the possible reduction in costs of fewer physician appointments. Hesselius 2005 used a valuation of SEK 445 for a physician appointment, which is extremely high compared to the average compensation per day received by the participating workers (SEK 296, which compensated 90% to 100% of lost wages).

However, the authors provided no information on the costs of potential laboratory tests, X‐rays, prescriptions, control appointments, or other costs related to the required physician appointment, nor could we make a reliable assumption of these costs. Consequently, our cost‐benefit calculation is far from ideal.

In summary, we found very low‐certainty evidence that introducing self‐certification of sickness absence or prolonging the self‐certification period has inconsistent effects on the mean number of sickness absence days, the number of sickness absence periods, and the amount of lost work time due to sickness absence periods.

We found no studies on the effects of self‐certification on social climate, supervisor involvement, workload or presenteeism.

Overall completeness and applicability of evidence

Only five studies met our inclusion criteria. Three of the five studies were carried out in Norway, one in Sweden, and one in the UK. Differences in disability policies, social security systems and working life, and cultures between countries might reduce the generalisability of the findings to other countries with different social contexts. Two of the studies were rather old. Taylor 1969 introduced self‐certification in the 1960s, and Hesselius 2005 reported a trial conducted in the 1980s, when working life and culture were quite different from how they are currently. This is important because self‐certification is assumed to have an effect on behaviour, which is also dependent on cultural factors.

Quality of the evidence

We judged the single included RCT to have a high risk of bias overall because it had a high risk of bias for sequence generation, allocation concealment, and blinding of participants and personnel. The study used alternation to allocate participants to the intervention or control group, which yields a predictable sequence. We downgraded the certainty of evidence from the single RCT by two levels, that is from high to low, due to risk of bias. We downgraded the evidence from this study on lost work time to very low due to indirectness because we inferred the result from two other outcomes.

We downgraded the certainty of the evidence from the CBA studies from low to very low due to risk of bias because the authors did not take into account critical confounders. . Given the small number of included studies, we could not assess the possible influence of publication bias.

Potential biases in the review process

We carried out systematic searches in the most important electronic databases. We also conducted a search for unpublished trials. We attempted to minimise selection bias by using no time or language restrictions. While the possibility remains that we have missed relevant studies, we think this is unlikely. Due to the lack of reporting details in the studies, and because we could not obtain additional data from study authors, we had to make assumptions in order to calculate effect sizes. In order to calculate SDs of the number of sickness absence periods per worker for Taylor 1969, we had to assume a distribution of the number of short‐term sickness absence periods per person. We took this information from a more recent Finnish study (Lahelma 2013). As this might not have been appropriate for a much older British study, we performed a sensitivity analysis. We found that with a distribution of almost all workers reporting sick and more frequently, the SDs doubled, but the MD was still significantly different from zero, therefore we believe that these assumptions have not biased our results.

Self‐certification is not the only factor that affects the duration and frequency of sickness absence. These are also influenced by such factors as business cycle (Pichler 2015), industry and occupation (Leinonen 2018), as well as healthcare regulations (e.g. waiting times, pay schemes). In this Cochrane Review we focused on changes in self‐certification and subsequent changes in sickness absence. We assume that the context (e.g. business cycle, industry and occupation, compensation level, and waiting times) was very similar for the intervention and control groups.

Agreements and disagreements with other studies or reviews

We are not aware of other systematic reviews on the topic we have addressed in this review. Our conclusions differ from those made by the authors of the studies included in our review. Some studies reported that self‐certification of sickness absence reduced the length of sickness absence or the number of sickness absence periods, whereas others reported increases.

Logic model of the intervention
Figures and Tables -
Figure 1

Logic model of the intervention

PRISMA study flow diagram.
Figures and Tables -
Figure 2

PRISMA study flow diagram.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.
Figures and Tables -
Figure 3

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.
Figures and Tables -
Figure 4

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Comparison 1 Longer self‐certification versus shorter self‐certification, Outcome 1 Duration of periods.
Figures and Tables -
Analysis 1.1

Comparison 1 Longer self‐certification versus shorter self‐certification, Outcome 1 Duration of periods.

Comparison 1 Longer self‐certification versus shorter self‐certification, Outcome 2 Number of periods/worker.
Figures and Tables -
Analysis 1.2

Comparison 1 Longer self‐certification versus shorter self‐certification, Outcome 2 Number of periods/worker.

Comparison 1 Longer self‐certification versus shorter self‐certification, Outcome 3 Lost work time due to period of sickness absence.
Figures and Tables -
Analysis 1.3

Comparison 1 Longer self‐certification versus shorter self‐certification, Outcome 3 Lost work time due to period of sickness absence.

Summary of findings for the main comparison. Longer self‐certification compared to shorter self‐certification for reducing sickness absence in workers

Longer self‐certification compared to shorter self‐certification for reducing sickness absence in workers

Patient or population: workers
Setting: work organisations
Intervention: longer self‐certification period
Comparison: shorter self‐certification period

Outcomes

Impact

№ of participants
(studies)

Certainty of the evidence
(GRADE)

RCT: Average duration of sickness absence periods in days
Follow‐up: 6 months

SC ≤ 14 days vs ≤ 7 days led to a 0.67 days longer duration of sickness absence periods ≤ 29 days (95% CI 0.55 to 0.79) in 1 study.

237,391
(1 RCT)

⊕⊕⊝⊝
LOW 1

CBA: Average duration of sickness absence periods in days
Follow‐up: 1 year

SC ≤ 3 days vs SC 0 days led to 0.32 days shorter duration of sickness absence periods ≤ 3 days (95% CI −0.39 to −0.25) in 1 study. SC ≤ 365 days vs ≤ 3 days did not lead to a change according to the authors.

1869
(2 observational studies)

⊕⊝⊝⊝
VERY LOW 2 3

RCT: Number of sickness absence periods per worker
Follow‐up: 6 months

SC ≤ 14 days led to no difference in the number of sickness absence periods compared to SC ≤ 7 days, but the authors did not report numerical data.

237,391
(1 RCT)

⊕⊕⊝⊝
LOW 1

CBA: Number of sickness absence periods per worker
Follow‐up: 1 year

SC ≤ 3 days vs SC 0 days led to an increase in 1 study (0.48 sickness absence periods lasting ≤ 3 days, 95% CI 0.33 to 0.63), and SC ≤ 365 days vs ≤ 3 days did not lead to a considerable difference in the number of sickness absence periods, but the authors did not report numerical data.

1869
(2 observational studies)

⊕⊝⊝⊝
VERY LOW 2 3

RCT: Average lost work time per 100 person‐years
Follow‐up: 6 months

SC ≤ 14 days vs SC ≤ 7 days led to an inferred increase in lost work time.

237,391
(1 RCT)

⊕⊝⊝⊝
LOW 1 4

CBA: Average lost work time per 100 person‐years
Follow‐up: 1 year

SC ≤ 3 days vs 0 days led to 0.54 days more lost work time (95% CI 0.47 to 0.61) in 1 study. SC ≤ 5 days vs SC ≤ 3 days led to 1.38 days (95% CI 1.16 to 1.60) more lost work time in absence periods of ≤ 3 and 0.1 days (95% CI could not be calculated) in absence periods of 4 to 16 days in 1 study. SC ≤ 50 days vs SC ≤ 3 days led to 0.65 days less lost work time in 1 study based on absence periods of 4 to 16 days. SC ≤ 365 days vs SC ≤ 3 days led to a decrease of −2.84 days in lost work time (95% CI −3.35 to −2.33) based on absence periods of > 16 days.

17,114
(4 observational studies)

⊕⊝⊝⊝
VERY LOW 2 5

RCT: Costs of sickness absence and physician certification

The cost of 1 day of sickness absence (SEK 296) was obtained using the average daily compensation paid by employers to employees. Given the cost of a physician appointment (SEK 445), the higher costs of sickness absence benefits (SEK 29,000,000) far outweighed the possible reduction in costs of fewer physician appointments (SEK 4,900,000) during 1 year.

237,391
(1 RCT)

⊕⊕⊝⊝
LOW 1

CBA: controlled before‐after study; CI: confidence interval; RCT: randomised controlled trial; SC: self‐certification, which means that a worker is allowed to take short periods (of a predetermined maximum length) of sick leave due to minor illnesses without obtaining an official document from a doctor (i.e. physician certification).

GRADE Working Group grades of evidence
High certainty: We are very confident that the true effect lies close to that of the estimate of the effect.
Moderate certainty: We are moderately confident in the effect estimate: the true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different.
Low certainty: Our confidence in the effect estimate is limited: the true effect may be substantially different from the estimate of the effect.
Very low certainty: We have very little confidence in the effect estimate: the true effect is likely to be substantially different from the estimate of effect.

1We downgraded the certainty of evidence by two levels, that is from high to moderate and then from moderate to low, due to risk of bias. The authors performed randomisation by date of birth, which is an inadequate randomisation method, and they did not blind participants or intervention providers.
2We downgraded the certainty of evidence by one level, that is from low to very low, due to risk of bias because the authors did not take critical confounders into account. Given the small number of included studies, we could not assess the possible influence of publication bias. We found no reason to upgrade the certainty of the evidence.
3We would have downgraded the certainty of evidence by one more level due to inconsistency because two studies produced opposing results, but we had already reached very low certainty.
4We downgraded the certainty of evidence by one level, that is from low to very low, due to indirectness because we inferred the conclusion about lost work time from two other outcomes.
5We would have downgraded the certainty of evidence by one more level due to inconsistency because results in studies with less self‐certification time showed an increase in lost work time, whereas two studies with much longer self‐certification showed a decrease in lost work time, but we had already reached very low certainty.

Figures and Tables -
Summary of findings for the main comparison. Longer self‐certification compared to shorter self‐certification for reducing sickness absence in workers
Comparison 1. Longer self‐certification versus shorter self‐certification

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Duration of periods Show forest plot

3

Mean Difference (IV, Fixed, 95% CI)

Totals not selected

1.1 Periods < 3 days

2

Mean Difference (IV, Fixed, 95% CI)

0.0 [0.0, 0.0]

1.2 Periods < 29 days

1

Mean Difference (IV, Fixed, 95% CI)

0.0 [0.0, 0.0]

2 Number of periods/worker Show forest plot

1

Mean Difference (IV, Fixed, 95% CI)

Totals not selected

2.1 Periods < 3 days

1

Mean Difference (IV, Fixed, 95% CI)

0.0 [0.0, 0.0]

3 Lost work time due to period of sickness absence Show forest plot

3

Mean Difference (Fixed, 95% CI)

Totals not selected

3.1 Periods < 3 days

2

Mean Difference (Fixed, 95% CI)

0.0 [0.0, 0.0]

3.2 Periods > 16 days

1

Mean Difference (Fixed, 95% CI)

0.0 [0.0, 0.0]

Figures and Tables -
Comparison 1. Longer self‐certification versus shorter self‐certification