Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-18T20:21:24.556Z Has data issue: false hasContentIssue false

Genetic Susceptibility to Sickness Absence is Similar Among Women and Men: Findings From a Swedish Twin Cohort

Published online by Cambridge University Press:  29 August 2012

Pia Svedberg*
Affiliation:
Division of Insurance Medicine, Department of Clinical Neuroscience, Karolinska Institutet, Stockholm, Sweden
Annina Ropponen
Affiliation:
Ergonomics, Institute of Biomedicine, Faculty of Health Sciences, University of Eastern Finland, Kuopio, Finland
Kristina Alexanderson
Affiliation:
Division of Insurance Medicine, Department of Clinical Neuroscience, Karolinska Institutet, Stockholm, Sweden
Paul Lichtenstein
Affiliation:
Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, Stockholm, Sweden
Jurgita Narusyte
Affiliation:
Division of Insurance Medicine, Department of Clinical Neuroscience, Karolinska Institutet, Stockholm, Sweden
*
address for correspondence: Pia Svedberg, PhD, Division of Insurance Medicine, Department of Clinical Neuroscience, Karolinska Institutet, Berzelius väg 3, 6th floor, SE-171 77 Stockholm, Sweden. E-mail: pia.svedberg@ki.se

Abstract

Previous studies of risk factors for sickness absence (SA) focus primarily on psychosocial and work environmental exposures. The aim of this study was to investigate the relative contribution of genetic influences on SA among women and men. The population-based study sample of Swedish twins (34,547) included 13,743 twin pairs of known zygosity, 3,495 monozygotic, 5,073 same-sexed dizygotic, and 5,175 opposite sexed. The point prevalence of long-term SA (≥15 days) in each zygosity and sex group was calculated. The risk of SA was estimated as an odds ratio (OR) with 95% confidence intervals (CI) where the odds for twins on SA to have a co-twin on SA was compared to the OR for SA in twins whose co-twin were not sickness absent. Intrapair correlations and probandwise concordance rates were calculated and standard biometrical genetic model-fitting methods were used to estimate the heritability of SA. The prevalence of SA was 8.8% (women 10.7%; men 6.5%). Intrapair similarity was higher among monozygotic than dizygotic twin pairs. The best-fitting model showed no sex differences in genetic effects or variance components contributing to SA. The heritability estimate was 36% (95% CI: 35–40%). Results suggest genetic contribution to the variation of SA and that environmental factors have an important role, for women and men. As SA seem to be influenced by genetic factors, future studies of associations between risk factors and SA should consider this potentially confounding effect.

Type
Articles
Copyright
Copyright © The Authors 2012

Several studies have investigated risk factors for sickness absence (SA) as well as factors predicting the duration of a sick leave spell (Alexanderson & Norlund, Reference Alexanderson and Norlund2004a, Reference Alexanderson and Norlund2004b; Dekkers-Sanchez et al., Reference Dekkers-Sanchez, Hoving, Sluiter and Frings-Dresen2008; Steenstra et al., Reference Steenstra, Verbeek, Heymans and Bongers2005). Focus has been on different types of psychosocial and work environmental factors, and the variation in those were suggested to be affected by selection, for instance selection into certain types of jobs, social context, or lifestyle (Alexanderson & Norlund, Reference Alexanderson and Norlund2004a, Reference Alexanderson and Norlund2004b; Allebeck & Mastekaasa, Reference Allebeck and Mastekaasa2004). Even though some studies have included information on the diagnosis underlying the work incapacity, mostly biological factors including genetic, have not been studied, mainly due to lack of such data. Nevertheless, influence of genetic factors may affect the estimations of the influential factors on SA if present, since genetic factors may be unknown confounders in studies of associations between risk factors and SA (Alexanderson & Norlund, Reference Alexanderson and Norlund2004a, Reference Alexanderson and Norlund2004b; Allebeck & Mastekaasa, Reference Allebeck and Mastekaasa2004; Pietikäinen et al., Reference Pietikäinen, Silventoinen, Svedberg, Alexanderson, Huunan-Seppälä, Koskenvuo, Koskenvuo, Kaprio and Ropponen2011; Ropponen et al., Reference Ropponen, Narusyte, Alexanderson and Svedberg2011a, Reference Ropponen, Silventoinen, Svedberg, Alexanderson, Koskenvuo, Huunan-Seppälä, Koskenvuo and Kaprio2011b; Samuelsson et al., Reference Samuelsson, Ropponen, Alexanderson, Lichtenstein and Svedberg2012). Studies of twins would provide additional insight into these issues.

One prerequisite for sickness benefits is the presence of a disease or injury, the other prerequisite is that this disease or injury has led to work incapacity. The pathways leading to SA might include biological factors affected by the presence of a disease or health symptoms, but also factors related to the work situation, insurance system, family background, socio-economy, demography, lifestyle, and culture can influence the SA of a person (Alexanderson & Norlund, Reference Alexanderson and Norlund2004b; Allebeck & Mastekaasa, Reference Allebeck and Mastekaasa2004; Pietikäinen et al., Reference Pietikäinen, Silventoinen, Svedberg, Alexanderson, Huunan-Seppälä, Koskenvuo, Koskenvuo, Kaprio and Ropponen2011; Ropponen et al., Reference Ropponen, Narusyte, Alexanderson and Svedberg2011a, Reference Ropponen, Silventoinen, Svedberg, Alexanderson, Koskenvuo, Huunan-Seppälä, Koskenvuo and Kaprio2011b; Samuelsson et al., Reference Samuelsson, Ropponen, Alexanderson, Lichtenstein and Svedberg2012). Thus, familial (genetic and family/early environment) as well as environmental factors may have important roles in individual differences in SA. So far, no twin or family study has investigated the relative contribution of genetic and environmental factors to SA. However, two recent studies have investigated genetic liability to disability pension (DP) (Harkonmaki et al., Reference Harkonmaki, Silventoinen, Levalahti, Pitkaniemi, Huunan-Seppala, Klaukka, Koskenvuo and Kaprio2008; Narusyte et al., Reference Narusyte, Ropponen, Silventoinen, Alexanderson, Kaprio, Samuelsson and Svedberg2011). DP is defined as an ultimate consequence of permanent work incapacity due to medical causes, and genetic factors were shown to contribute to the liability to DP to a moderate degree (24–49%), somewhat varying depending on DP diagnose group (Harkonmaki et al., Reference Harkonmaki, Silventoinen, Levalahti, Pitkaniemi, Huunan-Seppala, Klaukka, Koskenvuo and Kaprio2008; Narusyte et al., Reference Narusyte, Ropponen, Silventoinen, Alexanderson, Kaprio, Samuelsson and Svedberg2011). Diagnoses behind SA are to a large extent the same as those behind DP, that is, mental and musculoskeletal diagnoses (Hansson & Jensen, Reference Hansson and Jensen2004; Järvisalo et al., Reference Järvisalo, Raitasalo, Salminen, Klaukka, Kinnunen, Järvisalo, Andersson, Boedeker and Houtman2005). However, there might also be a variety of other SA diagnoses that cause work incapacity for a shorter time period that does not necessarily lead to permanent work incapacity and subsequent DP.

The present study aims to investigate the relative contribution of genetic and environmental factors for being SA among women and men in a large population-based Swedish twin cohort. A comparison of SA in monozygotic (MZ) and dizygotic (DZ) twin pairs would provide new insights on whether genetic factors influence SA. Inclusion of both women and men and opposite-sexed (OS) twins also enables further investigation of sex differences in the relative importance of genetic factors as well as whether different genes operate in women than in men. We expect that MZ twins are more similar than DZ twins for SA, based on previous findings of such similarities regarding DP and in occurrence of common diseases (Harkonmaki et al., Reference Harkonmaki, Silventoinen, Levalahti, Pitkaniemi, Huunan-Seppala, Klaukka, Koskenvuo and Kaprio2008; Narusyte et al., Reference Narusyte, Ropponen, Silventoinen, Alexanderson, Kaprio, Samuelsson and Svedberg2011; Plomin et al., Reference Plomin, Owen and McGuffin1994, Reference Plomin, DeFries, McClearn and McGuffin2000).

Methods

Participants and Data Sources

This study is based on the Swedish Twin study Of Disability pension and Sickness absence (STODS), established in 2009 (Svedberg et al., Reference Svedberg, Ropponen, Lichtenstein and Alexanderson2010). STODS includes twins born in Sweden between 1925 and 1958 (29,799 twin pairs) who were identified through the Swedish Twin Registry (STR) (Lichtenstein et al., Reference Lichtenstein, De faire, Floderus, Svartengren, Svedberg and Pedersen2002). Individuals who were on DP, old-age pension, or who were 65 years or older at January 1, 2002 were excluded. Hence, the study sample (n = 34,547) included twins born 1938–1958 (49.4% women) whereof 13,743 twin pairs of known zygosity; 3,495 MZ, 5,073 same-sexed DZ, and 5,175 OS DZ pairs.

All people living in Sweden with income from work or unemployment benefits are covered by the public Social Insurance, providing sickness benefits when disease or injury has lead to work incapacity, covering about 80% of lost income. SA data were retrieved from the Swedish National Social Insurance Agency's MiDAS database. For employees, sick pay is provided by the employer for the first 14 days of a SA spell, and thus not included in the MiDAS database. Data on death was obtained from the National Board of Health and Welfare, and data on old-age pension were obtained from Statistics Sweden. All registry data was linked to the twins by using the unique 10-digit personal identification number assigned to all Swedish residents.

Measures

Being long-term SA was defined as a binary variable (yes/no) based on the data in the MiDAS database at the National Social Insurance Agency at January 1, 2002, that is, having an ongoing sick leave spell of a duration of at least 15 days at this date.

In order to establish the zygosity of the like-sexed twin pairs, a series of questions about similarity was asked at the time of STR compilation. If twins in a pair did not agree on similarity, these questions were repeated in a later interview. The zygosity diagnosis was confirmed using DNA markers in a subset of the sample, and proved correct in 98% of the pairs (Lichtenstein et al., Reference Lichtenstein, De faire, Floderus, Svartengren, Svedberg and Pedersen2002, Reference Lichtenstein, Sullivan, Cnattingius, Gatz, Johansson, Carlstrom, Björk, Svartengren, Wolk, Klareskog, de Faire, Schalling, Palmgren and Pedersen2006).

Design and Statistical Analysis

Cross-sectional data analyses were conducted. The point prevalence of SA in each zygosity and sex group was calculated as the number of individuals on SA compared to all individuals in the group. The risk of SA was estimated as an odds ratio (OR) with 95% confidence intervals (CI) where the odds for twins on SA to have a co-twin on SA was compared to the odds for SA in twins whose co-twin was not sickness absent. Twin similarity in a pair was measured by calculating intrapair tetrachoric correlations as well as probandwise concordance rates. These rates refer to the conditional probability that one twin is affected, given that his or her co-twin is affected, which is compared with the probability of SA for an individual in the general population. SAS statistical software was used for these analyses (SAS Institute Inc, 2003).

Standard biometrical genetic model-fitting methods were used to investigate the heritability of SA, i.e., the proportion of variance accounted for by genetic factors. Genetic models were fitted to the raw ordinal data by maximum likelihood using Mx (Neale et al., Reference Neale, Boker, Xie and Maes2006). Analyses focused on fitting models allowing for additive (A) genetic effects plus shared (C) and nonshared (E) environmental effects. The goodness-of-fit of the full ACE model (i.e., the model including all A, C, and E effects) was compared to that of the restricted models (AE, CE, and E) by likelihood ratio tests. Akaike's information criterion (AIC) is an index of both goodness-of-fit and parsimony, which was also calculated for each fitted model. The model with the lowest AIC value was chosen as the best-fitting model, explaining the data in the most parsimonious way. Inclusion of opposite-sex twins provides an opportunity to test whether different genes are operating in women than in men (Kendler et al., Reference Kendler, Neale, Kessler, Heath and Eaves1992; Neale et al., Reference Neale, Boker, Xie and Maes2006). If contributing genetic effects are not the same between the two sexes, the estimated genetic correlation (rg) for the opposite-sex twins should be significantly different from a genetic correlation between the same-sex DZ twins, that is, 0.5. For estimation of all variance components as well as rg, we used all zygosity and sex groups simultaneously (MZ male, DZ male, MZ female, DZ female, DZ OS male–female, DZ OS female–male). We started out by fitting a model with all parameters being freely estimated, that is, ACE and prevalence parameters were different for women and men, as well as freely estimated rg (Model 1). Thereafter, the following restricted models were tested: Model 2 included free ACE parameters, but the same prevalence parameters for men and women, and freely estimated rg. Model 3 included free ACE parameters, but different prevalence parameters for men and women, and rg fixed at 0.5. Model 4 constrained ACE parameters to be equal across sex and rg fixed at 0.5, but different prevalence for men and women. Models 5 and 6 were the submodels AE and CE, respectively.

The study was reviewed and approved by the Regional Ethical Committee in Stockholm, Sweden.

Results

Among all individuals in the study sample (34,547), 2,964 twins were identified as having a long-term SA spell (8.6%) at January 1, 2002. SA was more prevalent among women (10.7%) than men (6.5%). The probandwise concordance rates were higher among MZ than DZ twin pairs and the tetrachoric intrapair correlations for each zygosity and sex group are presented in Table 1. The correlations in the MZ twin pairs were higher than the within pair correlations for DZ twin pairs in both sexes, suggesting a significant contribution of genetic factors in SA. The correlations for MZ female twin pairs were somewhat higher than the MZ male correlations suggesting sex differences in heritability. Further, the correlation in DZ OS twin pairs was lower (0.08) than the correlations for DZ same-sexed twin pairs (r = 0.17 for women, r = 0.12 for men), suggesting sex differences in genetic effects for SA.

TABLE 1 Number of Concordant Twin Pairs, Probandwise Concordance Rates, Odds Ratios (OR) with 95% Confidence Intervals (CI), and Tetrachoric (Intraclass) Correlations of Sickness Absence (SA) in a Swedish Twin Cohort for Monozygotic (MZ), Dizygotic (DZ) Same-Sexed, and DZ Opposite-Sexed (OS) Pairs

aAn individual's risk of SA (the conditional probability that one twin is affected, given that his or her co-twin is affected) and as such can be compared with the probability of SA for an individual in the general population. bThe risk of SA was calculated as an odds ratio where the odds for individuals on SA having a twin partner on SA was compared to the odds for SA in a twin whose co-twin were not sickness absent.

All the ORs were statistically significant for all zygosity groups by sex except for same-sexed DZ male twins. ORs were higher for MZ than DZ twins with MZ women showing the highest risk (OR = 4.61, CI = 3.11–6.86) (Table 1).

Before conducting the biometrical genetic analyses, a saturated model was used to test assumptions of twin models, and it was possible to constrain the thresholds for SA to be equal in twin 1 and twin 2 in a pair, in MZ and DZ same-sex pairs, and in same-sex and opposite-sex pairs.

The model fitting started with a full model (Model 1 in Tables 2 and 3). In Model 1, additive genetic effects (A), shared environmental effects (C) and nonshared environmental effects (E) were allowed to vary across sexes, different prevalence levels were allowed for men and women (two thresholds), and the genetic correlation for OS twins (rg) was estimated. Second, we tested for the same prevalence in men and women (Model 2), which resulted in deterioration of fit. Therefore, the subsequent models used different thresholds for men and women.

TABLE 2 Model Fit Statistics For the Univariate Model of Genetic and Environmental Effects in Liability to Sickness Absence in a Swedish Twin Cohort

LL = log-likelihood; df = degrees of freedom. aBest-fitting and the most parsimonious submodel (AE allowing different thresholds for women and men) indicated by the lowest Akaike's information criteria (AIC) value. Model 1 (full model): ACE women ≠ ACE men, different threshold for males and females, rg estimated. Model 2: ACE women ≠ ACE men, same threshold for males and females, rg estimated. Model 3: ACE women ≠ ACE men, different threshold for males and females, rg fixed. Model 4: ACE women = ACE men, different threshold for males and females, rg fixed. Model 5: AE women = AE men, different threshold for males and females, rg fixed. Model 6: CE women = CE men, different threshold for males and females. Model 7: E women = E men, different threshold for males and females.

TABLE 3 Parameter Estimates of Genetic and Environmental Effects with 95% Confidence Intervals (CI) in Liability for Sickness Absence in a Swedish Twin Cohort from Univariate Model-Fitting, Full Model, and Most Parsimonious (Best-Fitting) Model

aFull model: ACE women ≠ ACE men, different thresholds for males and females, rg estimated. bBest-fitting and the most parsimonious submodel (AE women = AE men, allowing different thresholds for women and men), and rg fixed, as indicated by the lowest Akaike's information criteria (AIC) value.

We fixed the genetic correlation for the opposite-sex twins to be equal to that of same-sexed DZ pairs (Model 3, rg = 0.5) and no significant deterioration of fit was observed. Model 4 constrained ACE to be equal for men and women. Again, there was no deterioration in fit, thus providing no evidence for gender-specific effects. Working from Model 4, we compared the equal ACE model to an AE model (Model 5). The latter model was preferred to the ACE model by the AIC criterion because of greater parsimony. The CE model (Model 6) was then fitted resulting in a poorer fit than the AE model according to AIC. The model which assumes no resemblance for SA (E) fitted poorly and was also rejected. Fit statistics and model-fitting results are presented in Tables 2 and 3.

The most parsimonious and best-fitting model according to AIC was the AE model (Model 5) with no shared environment (C), equal estimates for men and women, and rg fixed to 0.5. The results of the model fitting for this model and for the full model are provided in Table 3. In the best-fitting model, heritability was estimated at 35.6% (95% CI: 31.3–39.6%), with no sex differences in neither genetic effects nor the other variance components contributing to SA. However, prevalence of SA differed between sexes.

Discussion

This study investigated genetic liability to SA in a Swedish twin cohort of 35,000 adults aged 43–65 years. We found no support for sex differences in genetic factors contributing to SA even though prevalence of SA differed between women and men, i.e., more women than men were on SA.

To the best of our knowledge, no twin study has so far investigated the relative contribution of genetic and environmental factors to SA. The heritability of SA was 36% and of equal importance for women and men in the present study, similar to estimates recently shown for DP (Harkonmaki et al., Reference Harkonmaki, Silventoinen, Levalahti, Pitkaniemi, Huunan-Seppala, Klaukka, Koskenvuo and Kaprio2008; Narusyte et al., Reference Narusyte, Ropponen, Silventoinen, Alexanderson, Kaprio, Samuelsson and Svedberg2011). Genetic factors may reflect genetic liability to disease, such as cardiovascular disease (Evans et al., Reference Evans, Van Baal, McCarron, DeLange, Soerensen, De Geus, Kyvik, Pedersen, Spector, Andrew, Patterson, Whitfield, Zhu, Martin, Kaprio and Boomsma2003; Zdravkovic et al., Reference Zdravkovic, Wienke, Pedersen and de Faire2007), depression (Kendler et al., Reference Kendler, Gatz, Gardner and Pedersen2006; Orstavik et al., Reference Orstavik, Kendler, Czajkowski, Tambs and Reichborn-Kjennerud2007), diabetes (Hyttinen et al., Reference Hyttinen, Kaprio, Kinnunen, Koskenvuo and Tuomilehto2003), musculoskeletal disorders (Battie et al., Reference Battie, Videman, Levalahti, Gill and Kaprio2007; MacGregor et al., Reference MacGregor, Andrew, Sambrook and Spector2004), or functional ability (Christensen et al., Reference Christensen, McGue, Yashin, Iachine, Holm and Vaupel2000). As diagnoses behind SA to a large extent are the same as those behind DP, which are, mental and musculoskeletal diagnoses (Hansson & Jensen, Reference Hansson and Jensen2004; Järvisalo et al., Reference Järvisalo, Raitasalo, Salminen, Klaukka, Kinnunen, Järvisalo, Andersson, Boedeker and Houtman2005), this result could be expected. However, contrary to our expectations, the heritability of SA was not lower than that of DP. A greater variety of diagnoses, also co-occurring, might be expected behind SA that cause work incapacity for a shorter time period and hence does not necessarily lead to permanent work incapacity. Most SA spells do not lead to DP. Conditions that initially cause SA either resolve through a natural course or can to a large extent be dealt with thorough medication or other treatments, also true for many chronic conditions, such as diabetes or cardiovascular diseases (Evans et al., Reference Evans, Van Baal, McCarron, DeLange, Soerensen, De Geus, Kyvik, Pedersen, Spector, Andrew, Patterson, Whitfield, Zhu, Martin, Kaprio and Boomsma2003; Hyttinen et al., Reference Hyttinen, Kaprio, Kinnunen, Koskenvuo and Tuomilehto2003). Other common medical diagnoses behind SA that seldom cause permanent exclusion from the working life include influenza, pneumonia, gastrointestinal diseases, recurrent headache or migraine, asthma, chronic widespread pain, and chronic fatigue, some being more heritable conditions than others (Burgner & Levin, Reference Burgner and Levin2003; Ekbom et al., Reference Ekbom, Svensson, Pedensen and Waldenlind2006; Kato et al., Reference Kato, Sullivan, Evengård and Pedersen2009; Svedberg et al., Reference Svedberg, Johansson, Wallander and Pedersen2008; Svensson, Reference Svensson2004). Hence, one could also have expected that the broader variety of medical reasons behind SA than DP could have resulted in a lower heritability estimate for SA than reported for DP.

We also expected that twins in a pair would less likely be on SA at the same time as compared to for example twin similarity in DP. This expectation was based on our use of ongoing SA spells (≥15 days) at a specific date that were then considered as a binary measure of SA. However, as this prevalence measure included SA starting and ongoing at that time point despite of the length, recurrence, or diagnosis of SA, it might have increased the pairwise concordances. Also, this SA measure based on register data can be considered as long-term SA. Furthermore, among those on SA with one diagnosis, there is often a wide variance in future SA diagnoses whereof some might lead to permanent incapacity to work and DP (Hagberg et al., Reference Hagberg, Vaez and Alexanderson2010; Vaez et al., Reference Vaez, Rylander, Nygren, Asberg and Alexanderson2007, Reference Vaez, Hagberg and Alexanderson2009).

Environmental factors also had an important role in individual differences in SA and may be related to adulthood choices or other factors unique to each individual. Several studies have, for example, shown that work environmental factors, mainly physical but also psychosocial factors (Burr et al., Reference Burr, Pedersen and Hansen2011; Christensen et al., Reference Christensen, Nielsen, Rugulies, Smith-Hansen and Kristensen2005; Labriola et al., Reference Labriola, Christensen, Lund, Nielsen and Diderichsen2006; Lund et al., Reference Lund, Labriola, Christensen, Bultmann and Villadsen2006; Nielsen et al., Reference Nielsen, Rugulies, Smith-Hansen, Christensen and Kristensen2006; Voss et al., Reference Voss, Floderus and Diderichsen2004), lifestyle (Laaksonen et al., Reference Laaksonen, Piha, Martikainen, Rahkonen and Lahelma2009; Robroek et al., Reference Robroek, van den Berg, Plat and Burdorf2011), and pain (Saastamoinen et al., Reference Saastamoinen, Laaksonen, Lahelma and Leino-Arjas2009) are associated with SA. Further, some recent twin studies of the associations between socio-demography, health-related factors, pain, and DP showed that the associations seem to be independent from familial effects or influenced by those to a minor degree (Pietikäinen et al., Reference Pietikäinen, Silventoinen, Svedberg, Alexanderson, Huunan-Seppälä, Koskenvuo, Koskenvuo, Kaprio and Ropponen2011; Ropponen et al., Reference Ropponen, Narusyte, Alexanderson and Svedberg2011a, Reference Ropponen, Silventoinen, Svedberg, Alexanderson, Koskenvuo, Huunan-Seppälä, Koskenvuo and Kaprio2011b; Samuelsson et al., Reference Samuelsson, Ropponen, Alexanderson, Lichtenstein and Svedberg2012).

In contrast to previous results of genetic liability to DP (Narusyte et al., Reference Narusyte, Ropponen, Silventoinen, Alexanderson, Kaprio, Samuelsson and Svedberg2011), we found no support of different pathways to SA for women and men. However, further large studies including specific diagnoses are necessary to investigate the complexity of sex and diagnose-specific effects of both SA and DP more precisely. In line with previous studies of genetic liability to DP we found no effects of shared environment (Harkonmaki et al., Reference Harkonmaki, Silventoinen, Levalahti, Pitkaniemi, Huunan-Seppala, Klaukka, Koskenvuo and Kaprio2008; Narusyte et al., Reference Narusyte, Ropponen, Silventoinen, Alexanderson, Kaprio, Samuelsson and Svedberg2011). This finding does not necessarily imply that such factors are unimportant, only that they are not important for individual differences in SA.

Strengths and Limitations

This was a large population-based study including both same-sexed and opposite-sex twin pairs. Ascertainment bias that sometimes is a problem in twin studies was unlikely to occur since the register data of SA were of high quality and covers all individuals over the age of 16 in the Swedish population that were granted SA benefits. Further, occurrence of SA in the twin cohort was comparable to the official statistics of the Swedish National Social Insurance Agency (Försäkringskassan (Swedish Social Insurance Agency), 2011). A limitation in this study was that information on SA diagnoses was not available. Having in mind results from previous studies of DP (Harkonmaki et al., Reference Harkonmaki, Silventoinen, Levalahti, Pitkaniemi, Huunan-Seppala, Klaukka, Koskenvuo and Kaprio2008; Narusyte et al., Reference Narusyte, Ropponen, Silventoinen, Alexanderson, Kaprio, Samuelsson and Svedberg2011), it is possible that the heritability estimates would differ depending on the medical diagnosis behind SA. Also, as younger adults below age 40 were not included in the present study, the results cannot be generalized to young adults. Further, information on short-term SA spells were not available, i.e., the relative importance of genetic and environmental factors for the very short SA might differ from our findings.

Conclusions

Both genetic and environmental factors seem to have important roles for individual differences in SA, contributing in a similar way in women and men. The relatively large proportion of the variance in SA explained by environmental factors emphasizes the importance to continue to identify and address specific environmental stressors when planning intervention strategies for people at risk for SA. However, and more importantly, as SA seem to be influenced by genetic factors, future studies of associations between risk factors and SA should consider this potentially confounding effect.

References

Alexanderson, K., & Norlund, A. (2004a). Swedish Council on Technology Assessment in Health Care (SBU). Chapter 1. Aim, background, key concepts, regulations, and current statistics. Scandinavian Journal of Public Health, 32, 1230.CrossRefGoogle Scholar
Alexanderson, K., & Norlund, A. (2004b). Swedish Council on Technology Assessment in Health Care (SBU). Chapter 12. Future need for research. Scandinavian Journal of Public Health, 32, 256258.CrossRefGoogle Scholar
Allebeck, P., & Mastekaasa, A. (2004). Risk factors for sick leave—general studies. Scandinavian Journal of Public Health, 32, 49108.CrossRefGoogle Scholar
Battie, M. C., Videman, T., Levalahti, E., Gill, K., & Kaprio, J. (2007). Heritability of low back pain and the role of disc degeneration. Pain, 131, 272280.CrossRefGoogle ScholarPubMed
Burgner, D., & Levin, M. (2003). Genetic susceptibility to infectious diseases. The Pediatric Infectious Disease Journal, 22, 16.CrossRefGoogle ScholarPubMed
Burr, H., Pedersen, J., & HansenV., Jr. V., Jr. (2011). Work environment as predictor of long-term sickness absence: Linkage of self-reported DWECS dat with the DREAM register. Scandinavian Journal of Public Health, 39, 147152.CrossRefGoogle Scholar
Christensen, K., McGue, M., Yashin, A., Iachine, I., Holm, N. V., & Vaupel, J. W. (2000). Genetic and environmental influences on functional abilities in Danish twins aged 75 years and older. Journals of Gerontology A Biological Science Medical Science, 55, M446452.CrossRefGoogle ScholarPubMed
Christensen, K. B., Nielsen, M. L., Rugulies, R., Smith-Hansen, L., & Kristensen, T. S. (2005). Workplace levels of psychosocial factors as prospective predictors of registered sickness absence. Journal of Occupational & Environmental Medicine, 47, 933940.CrossRefGoogle ScholarPubMed
Dekkers-Sanchez, P. M., Hoving, J. L., Sluiter, J. K., & Frings-Dresen, M. H. (2008). Factors associated with long-term sick leave in sick-listed employees: A systematic review. Occupupational & Environmental Medicine, 65, 153157.CrossRefGoogle ScholarPubMed
Ekbom, K., Svensson, D. A., Pedensen, N. L., & Waldenlind, E. (2006). Lifetime prevalence and concordance risk of cluster headache in the Swedish twin population. Neurology, 67, 798803.CrossRefGoogle ScholarPubMed
Evans, A., Van Baal, G. C., McCarron, P., DeLange, M., Soerensen, T. I., De Geus, E. J., Kyvik, K., Pedersen, N. L., Spector, T. D., Andrew, T., Patterson, C., Whitfield, J. B., Zhu, G., Martin, N. G., Kaprio, J., & Boomsma, D. I. (2003). The genetics of coronary heart disease: The contribution of twin studies. Twin Research, 6, 432441.CrossRefGoogle ScholarPubMed
Försäkringskassan (Swedish Social Insurance Agency). (2011). Social insurance in figures 2011. Stockholm: Försäkringskassan (The Swedish Social Insurance Agency). Retrieved from http://www.forsakringskassan.se/wps/wcm/connect/19bebf2a-468c-4d7d-ad9d7746b5659e4c/engelska_Social_Insurance_in_Figures_2011.pdf?MOD=AJPERESGoogle Scholar
Hagberg, J., Vaez, M., & Alexanderson, K. (2010). Methods for analysing individual changes in sick-leave diagnoses over time. Work, 36, 283293.CrossRefGoogle ScholarPubMed
Hansson, T., & Jensen, I. (2004). Swedish Council on Technology Assessment in Health Care (SBU). Chapter 6. Sickness absence due to back and neck disorders. Scandinavian Journal of Public Health, 32, 109151.CrossRefGoogle Scholar
Harkonmaki, K., Silventoinen, K., Levalahti, E., Pitkaniemi, J., Huunan-Seppala, A., Klaukka, T., Koskenvuo, M., & Kaprio, J. (2008). The genetic liability to disability retirement: A 30-year follow-up study of 24,000 Finnish twins. PLoS ONE, 3, e3402.CrossRefGoogle Scholar
Hyttinen, V., Kaprio, J., Kinnunen, L., Koskenvuo, M., & Tuomilehto, J. (2003). Genetic liability of type 1 diabetes and the onset age among 22,650 young Finnish twin pairs: A nationwide follow-up study. Diabetes, 52, 10521055.CrossRefGoogle Scholar
Järvisalo, J., Raitasalo, R., Salminen, J. K., Klaukka, T., & Kinnunen, E. (2005). Depression and other mental disporders, sickness absenteeism, and work disability pensions in Finland. In Järvisalo, J., Andersson, B., Boedeker, W., & Houtman, I. (Eds.), Mental disorders as a major challenge in prevention of work disability. Helsinki: KELA, 1–186.Google Scholar
Kato, K., Sullivan, P. F., Evengård, B., & Pedersen, N. L. (2009). A population-based twin study of functional somatic syndromes. Psychological Medicine, 39, 497505.CrossRefGoogle ScholarPubMed
Kendler, K., Neale, M., Kessler, R., Heath, A., & Eaves, L. (1992). Generalized anxiety disorder in women. A population-based twin study. Arch Gen Psychiatry, 49, 267272.CrossRefGoogle ScholarPubMed
Kendler, K. S., Gatz, M., Gardner, C. O., & Pedersen, N. L. (2006). A Swedish national twin study of lifetime major depression. American Journal of Psychiatry, 163, 109114.CrossRefGoogle ScholarPubMed
Laaksonen, M., Piha, K., Martikainen, P., Rahkonen, O., & Lahelma, E. (2009). Health-related behaviours and sickness absence from work. Occupational & Environmental Medicine, 66, 840847.CrossRefGoogle ScholarPubMed
Labriola, M., Christensen, K., Lund, T., Nielsen, M. L., & Diderichsen, F. (2006). Multilevel analysis of workplace and individual risk factors for long-term sickness absence. Journal of Occupational & Environmental Medicine, 48, 923929.CrossRefGoogle ScholarPubMed
Lichtenstein, P., De faire, U., Floderus, B., Svartengren, M., Svedberg, P., & Pedersen, N. L. (2002). The Swedish Twin Registry: A unique resource for clinical, epidemiological and genetic studies. Journal of Internal Medicine, 252, 184205.CrossRefGoogle ScholarPubMed
Lichtenstein, P., Sullivan, P. F., Cnattingius, S., Gatz, M., Johansson, S., Carlstrom, E., Björk, C., Svartengren, M., Wolk, A., Klareskog, L., de Faire, U., Schalling, M., Palmgren, J., & Pedersen, N. L. (2006). The Swedish Twin Registry in the third millennium: An update. Twin Research & Human Genetics, 9, 875882.CrossRefGoogle ScholarPubMed
Lund, T., Labriola, M., Christensen, K. B., Bultmann, U., & Villadsen, E. (2006). Physical work environment risk factors for long term sickness absence: Prospective findings among a cohort of 5357 employees in Denmark. BMJ, 332, 449452.CrossRefGoogle ScholarPubMed
MacGregor, A. J., Andrew, T., Sambrook, P. N., & Spector, T. D. (2004). Structural, psychological, and genetic influences on low back and neck pain: A study of adult female twins. Arthritis & Rheumatism, 51, 160167.CrossRefGoogle ScholarPubMed
Narusyte, J., Ropponen, A., Silventoinen, K., Alexanderson, K., Kaprio, J., Samuelsson, A., & Svedberg, P. (2011). Genetic liability to disability pension in women and men: A prospective population-based twin study. PLoS ONE, 6, e23143.CrossRefGoogle Scholar
Neale, M. C., Boker, S. M., Xie, G., & Maes, H. H. (2006). Mx: Statistical modelling (7th ed.). Richmond, VA: Department of Psychiatry, Medical College of Virginia.Google Scholar
Nielsen, M. L., Rugulies, R., Smith-Hansen, L., Christensen, K. B., & Kristensen, T. S. (2006). Psychosocial work environment and registered absence from work. Estimating the etiologic fraction. American Journal of Industrial Medicine, 49, 187196.CrossRefGoogle ScholarPubMed
Orstavik, R. E., Kendler, K. S., Czajkowski, N., Tambs, K., & Reichborn-Kjennerud, T. (2007). Genetic and environmental contributions to depressive personality disorder in a population-based sample of Norwegian twins. Journal of Affective Disorders, 99, 181189.CrossRefGoogle Scholar
Pietikäinen, S., Silventoinen, K., Svedberg, P., Alexanderson, K., Huunan-Seppälä, A., Koskenvuo, K., Koskenvuo, M., Kaprio, J., & Ropponen, A. (2011). Health-related and sociodemographic risk factors for disability pension due to low back disorders: A 30-year prospective Finnish twin cohort study. Journal of Occupational & Environmental Medicine, 53, 488496.CrossRefGoogle ScholarPubMed
Plomin, R., DeFries, J. C., McClearn, G. E., & McGuffin, P. (Eds.). (2000). Behavioral genetics (4th ed.). New York: Worth Publishers.Google Scholar
Plomin, R., Owen, M. J., & McGuffin, P. (1994). The genetic basis of complex human behaviors. Science, 264, 17331739.CrossRefGoogle ScholarPubMed
Robroek, S. J. W., van den Berg, T. I. J., Plat, J. F., & Burdorf, A. (2011). The role of obesity and lifestyle behaviours in a productive workforce. Occupational & Environmental Medicine, 68, 134139.CrossRefGoogle Scholar
Ropponen, A., Narusyte, J., Alexanderson, K., & Svedberg, P. (2011a). Stability and change in health behaviours as predictors for disability pension in general and due to musculoskeletal diagnosis: a prospective cohort study of Swedish twins. BMC Public Health, 11, 678.CrossRefGoogle ScholarPubMed
Ropponen, A., Silventoinen, K., Svedberg, P., Alexanderson, K., Koskenvuo, K., Huunan-Seppälä, A., Koskenvuo, M., & Kaprio, J. (2011b). Health related risk factors for disability pension due to musculoskeletal diagnoses: A 30-year Finnish twin cohort study. Scandinavian Journal of Public Health, 39, 839848.CrossRefGoogle ScholarPubMed
Saastamoinen, P., Laaksonen, M., Lahelma, E., & Leino-Arjas, P. (2009). The effect of pain on sickness absence among middle-aged municipal employees. Occupational & Environmental Medicine, 66, 131136.CrossRefGoogle ScholarPubMed
Samuelsson, Å., Ropponen, A., Alexanderson, K., Lichtenstein, P., & Svedberg, P. (2012). Prevalence of disability pension over a 16-year period and associations with sociodemographic factors: A cohort study of 53 000 twins in Sweden. Journal of Occupational & Environmental Medicine, 54, 1016.CrossRefGoogle Scholar
SAS Institute Inc. (2003). The SAS system, Version 9.1. Cary, NC: SAS Institute Inc.Google Scholar
Steenstra, I. A., Verbeek, J. H., Heymans, M. W., & Bongers, P. M. (2005). Prognostic factors for duration of sick leave in patients sick listed with acute low back pain: A systematic review of the literature. Occupational & Environmental Medicine, 62, 851860.CrossRefGoogle ScholarPubMed
Svedberg, P., Johansson, S., Wallander, M. A., & Pedersen, N. L. (2008). No evidence of sex differences in heritability of irritable bowel syndrome in Swedish twins. Twin Research & Human Genetics, 11, 197203.CrossRefGoogle ScholarPubMed
Svedberg, P., Ropponen, A., Lichtenstein, P., & Alexanderson, K. (2010). Are self-report of disability pension and long-term sickness absence accurate? Comparisons of self-reported interview data with national register data in a Swedish twin cohort. BMC Public Health, 10, 763.CrossRefGoogle Scholar
Svensson, D. A. (2004). Etiology of primary headaches: The importance of genes and environment. Expert Review of Neurotherapeutics, 4, 415424.CrossRefGoogle ScholarPubMed
Vaez, M., Hagberg, J., & Alexanderson, K. (2009). The panorama of future sick-leave diagnoses among young adults initially long-term sickness absent due to neck, shoulder, or back diagnoses. An 11-year prospective cohort study. BMC Musculoskeletal Disorders, 10, 84.CrossRefGoogle Scholar
Vaez, M., Rylander, G., Nygren, A., Asberg, M., & Alexanderson, K. (2007). Sickness absence and disability pension in a cohort of employees initially on long-term sick leave due to psychiatric disorders in Sweden. Social Psychiatry & Psychiatric Epidemiology, 42, 381388.CrossRefGoogle Scholar
Voss, M., Floderus, B., & Diderichsen, F. (2004). How do job characteristics, family situation, domestic work, and lifestyle factors relate to sickness absence? A study based on Sweden Post. Journal of Occupational & Environmental Medicine, 46, 11341143.CrossRefGoogle ScholarPubMed
Zdravkovic, S., Wienke, A., Pedersen, N. L., & de Faire, U. (2007). Genetic susceptibility of myocardial infarction. Twin Research & Human Genetics, 10, 848852.CrossRefGoogle ScholarPubMed
Figure 0

TABLE 1 Number of Concordant Twin Pairs, Probandwise Concordance Rates, Odds Ratios (OR) with 95% Confidence Intervals (CI), and Tetrachoric (Intraclass) Correlations of Sickness Absence (SA) in a Swedish Twin Cohort for Monozygotic (MZ), Dizygotic (DZ) Same-Sexed, and DZ Opposite-Sexed (OS) Pairs

Figure 1

TABLE 2 Model Fit Statistics For the Univariate Model of Genetic and Environmental Effects in Liability to Sickness Absence in a Swedish Twin Cohort

Figure 2

TABLE 3 Parameter Estimates of Genetic and Environmental Effects with 95% Confidence Intervals (CI) in Liability for Sickness Absence in a Swedish Twin Cohort from Univariate Model-Fitting, Full Model, and Most Parsimonious (Best-Fitting) Model