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Evaluation of a multimodal pain rehabilitation programme in primary care based on clinical register data: a feasibility study

Published online by Cambridge University Press:  14 January 2020

Charlotte Post Sennehed*
Affiliation:
Faculty of medicine, Department of Clinical Sciences Lund, Orthopedics, Lund University, Lund, Sweden Department of Research and Development, Region Kronoberg, Växjö, Sweden
Kjerstin Stigmar
Affiliation:
Department of Health Sciences, Medical Faculty, Lund University, Lund, Sweden R&D Department, Skåne University Hospital, Lund, Sweden
Birgitta Grahn
Affiliation:
Faculty of medicine, Department of Clinical Sciences Lund, Orthopedics, Lund University, Lund, Sweden Department of Research and Development, Region Kronoberg, Växjö, Sweden
Marcelo Rivano Fischer
Affiliation:
Faculty of Medicine, Research Group Rehabilitation Medicine, Health Sciences Center, Lund University,Lund, Sweden
Malin Forsbrand
Affiliation:
Faculty of medicine, Department of Clinical Sciences Lund, Orthopedics, Lund University, Lund, Sweden Blekinge Center of Competence,Region Blekinge, Karlskrona, Sweden
Anja Nyberg
Affiliation:
Department of Healthcare Governance, Region Skåne, Malmö, Sweden
Ingemar F. Petersson
Affiliation:
Faculty of medicine, Department of Clinical Sciences Lund, Orthopedics, Lund University, Lund, Sweden R&D Department, Skåne University Hospital, Lund, Sweden
Sara Holmberg
Affiliation:
Department of Research and Development, Region Kronoberg, Växjö, Sweden Division of Occupational and Environmental Medicine, Institute of Laboratory Medicine, Lund University, Lund, Sweden
*
Author for correspondence: Charlotte Post Sennehed, Faculty of Medicine, Department of Clinical Sciences Lund, Orthopedics, Lund University, Lund, Sweden. E-mail: [email protected]
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Abstract

Aim:

Investigate the feasibility of identifying a well-defined treatment group and a comparable reference group in clinical register data.

Background:

There is insufficient knowledge on how to avert neck/back pain from turning chronic or to impair work ability. The Swedish Government implemented a national multimodal rehabilitation (MMR) programme in primary care intending to promote work ability, reduce sick leave and increase return to work. Since randomised control trial data for effect is lacking, it is important to evaluate existing observational data from clinical settings.

Methods:

We identified all unique patients with musculoskeletal pain (MSP) diagnoses undergoing the MMR programme in primary care in the Skåne Health care Register (n = 2140) during 2010–2011. A reference cohort in primary care (n = 56 300) with similar MSP diagnoses, same ages and the same level of sick leave before baseline was identified for the same period. The reference cohort received ordinary care and treatment in primary care. The final study group consisted of 603 eligible MMR patients and 2874 eligible reference patients. Socio-economic and health-related baseline data including sick leave one year before up to two years after baseline were compared between groups.

Findings:

There were significant socio-economic and health differences at baseline between the MMR and the reference patients, with the MMR group having lower income, higher morbidity and more sick leave days. Sick leave days per year decreased significantly in the MMR group (118–102 days, P < 0.001) and in the reference group (50–42 days, P < 0.001) from one year before baseline to two years after.

Conclusions:

It was not feasible to identify a comparable reference group based on clinical register data. Despite an ambitious attempt to limit selection bias, significant baseline differences in socio-economic and health were present. In absence of randomised trials, effects of MMR cannot be sufficiently evaluated in primary care.

Type
Research
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s) 2020

Introduction

Musculoskeletal pain (MSP), mainly back and neck pain, is one of the major causes of decreased work ability in Western countries (Gerdle et al., Reference Gerdle, Bjork, Coster, Henriksson, Henriksson and Bengtsson2008; Bevan et al. Reference Bevan, Quadrello, Mcgee, Mahdon, Vavrovsky and Barham2009; Vos et al., Reference Vos, Flaxman, Naghavi, Lozano, Michaud, Ezzati, Shibuya, Salomon, Abdalla, Aboyans, Abraham, Ackerman, Aggarwal, Ahn, Ali, Alvarado, Anderson, Anderson, Andrews, Atkinson, Baddour, Bahalim, Barker-Collo, Barrero, Bartels, Basáñez, Baxter, Bell, Benjamin, Bennett, Bernabé, Bhalla, Bhandari, Bikbov, Bin Abdulhak, Birbeck, Black, Blencowe, Blore, Blyth, Bolliger, Bonaventure, Boufous, Bourne, Boussinesq, Braithwaite, Brayne, Bridgett, Brooker, Brooks, Brugha, Bryan-Hancock, Bucello, Buchbinder, Buckle, Budke, Burch, Burney, Burstein, Calabria, Campbell, Canter, Carabin, Carapetis, Carmona, Cella, Charlson, Chen, Cheng, Chou, Chugh, Coffeng, Colan, Colquhoun, Colson, Condon, Connor, Cooper, Corriere, Cortinovis, de Vaccaro, Couser, Cowie, Criqui, Cross, Dabhadkar, Dahiya, Dahodwala, Damsere-Derry, Danaei, Davis, De Leo, Degenhardt, Dellavalle, Delossantos, Denenberg, Derrett, Des Jarlais, Dharmaratne, Dherani, Diaz-Torne, Dolk, Dorsey, Driscoll, Duber, Ebel, Edmond, Elbaz, Ali, Erskine, Erwin, Espindola, Ewoigbokhan, Farzadfar, Feigin, Felson, Ferrari, Ferri, Fèvre, Finucane, Flaxman, Flood, Foreman, Forouzanfar, Fowkes, Franklin, Fransen, Freeman, Gabbe, Gabriel, Gakidou, Ganatra, Garcia, Gaspari, Gillum, Gmel, Gosselin, Grainger, Groeger, Guillemin, Gunnell, Gupta, Haagsma, Hagan, Halasa, Hall, Haring, Haro, Harrison, Havmoeller, Hay, Higashi, Hill, Hoen, Hoffman, Hotez, Hoy, Huang, Ibeanusi, Jacobsen, James, Jarvis, Jasrasaria, Jayaraman, Johns, Jonas, Karthikeyan, Kassebaum, Kawakami, Keren, Khoo, King, Knowlton, Kobusingye, Koranteng, Krishnamurthi, Lalloo, Laslett, Lathlean, Leasher, Lee, Leigh, Lim, Limb, Lin, Lipnick, Lipshultz, Liu, Loane, Ohno, Lyons, Ma, Mabweijano, MacIntyre, Malekzadeh, Mallinger, Manivannan, Marcenes, March, Margolis, Marks, Marks, Matsumori, Matzopoulos, Mayosi, McAnulty, McDermott, McGill, McGrath, Medina-Mora, Meltzer, Mensah, Merriman, Meyer, Miglioli, Miller, Miller, Mitchell, Mocumbi, Moffitt, Mokdad, Monasta, Montico, Moradi-Lakeh, Moran, Morawska, Mori, Murdoch, Mwaniki, Naidoo, Nair, Naldi, Narayan, Nelson, Nelson, Nevitt, Newton, Nolte, Norman, Norman, O’Donnell, O’Hanlon, Olives, Omer, Ortblad, Osborne, Ozgediz, Page, Pahari, Pandian, Rivero, Patten, Pearce, Padilla, Perez-Ruiz, Perico, Pesudovs, Phillips, Phillips, Pierce, Pion, Polanczyk, Polinder, Pope, Popova, Porrini, Pourmalek, Prince, Pullan, Ramaiah, Ranganathan, Razavi, Regan, Rehm, Rein, Remuzzi, Richardson, Rivara, Roberts, Robinson, De Leòn, Ronfani, Room, Rosenfeld, Rushton, Sacco, Saha, Sampson, Sanchez-Riera, Sanman, Schwebel, Scott, Segui-Gomez, Shahraz, Shepard, Shin, Shivakoti, Singh, Singh, Singh, Singleton, Sleet, Sliwa, Smith, Smith, Stapelberg, Steer, Steiner, Stolk, Stovner, Sudfeld, Syed, Tamburlini, Tavakkoli, Taylor, Taylor, Taylor, Thomas, Thomson, Thurston, Tleyjeh, Tonelli, Towbin, Truelsen, Tsilimbaris, Ubeda, Undurraga, van der Werf, van Os, Vavilala, Venketasubramanian, Wang, Wang, Watt, Weatherall, Weinstock, Weintraub, Weisskopf, Weissman, White, Whiteford, Wiersma, Wilkinson, Williams, Williams, Witt, Wolfe, Woolf, Wulf, Yeh, Zaidi, Zheng, Zonies, Lopez, Murray, AlMazroa and Memish2012). Patients with MSP constitute a large group seeking care in primary care (Jordan et al., Reference Jordan, Kadam, Hayward, Porcheret, Young and Croft2010; Kinge et al., Reference Kinge, Knudsen, Skirbekk and Vollset2015), rendering high costs both for the individual and society (Alexanderson and Norlund, Reference Alexanderson and Norlund2004; Gustavsson et al., Reference Gustavsson, Bjorkman, Ljungcrantz, Rhodin, Rivano-Fischer, Sjolund and Mannheimer2012). Early identification using prognostic screening has in recent studies shown positive results both in terms of patients’ improved health and cost-effectiveness (Hill et al., Reference Hill, Whitehurst, Lewis, Bryan, Dunn, Foster, Konstantinou, Main, Mason, Somerville, Sowden, Vohora and Hay2011; Forsbrand et al., Reference Forsbrand, Grahn, Hill, Petersson, Sennehed and Stigmar2017). There is various treatment options aimed at preventing acute/subacute back pain to deteriorate into chronic problems with decreased work ability, but there is insufficient evidence for these treatments (Swedish Agency for Health Technology Assessment and Assessment of Social Services; Waddell, Reference Waddell1987; Waddell and Burton, Reference Waddell and Burton2005).

There is moderate evidence for multidisciplinary rehabilitation compared to usual care (Kamper et al., Reference Kamper, Apeldoorn, Chiarotto, Smeets, Ostelo, Guzman and Van Tulder2015). Multidisciplinary rehabilitation has shown positive effect on function (Guzman et al., Reference Guzman, Esmail, Karjalainen, Malmivaara, Irvin and Bombardier2001) and there is evidence to support the use of advice to remain active (Liddle et al., Reference Liddle, Gracey and Baxter2007). When multidisciplinary rehabilitation has been combined with workplace interventions, it has been found to be effective (Williams et al., Reference Williams, Westmorland, Lin, Schmuck and Creen2007; Kuoppala et al., Reference Kuoppala, Lamminpaa and Husman2008). In Scandinavian settings, it is reported that multimodal rehabilitation (MMR) increases return-to-work (RTW) rate (Norlund et al., Reference Norlund, Ropponen and Alexanderson2009; Bakshi et al., Reference Bakshi, Brommels, Klinga, Bonnevier and Jensen2011; Busch et al., Reference Busch, Bodin, Bergström and Jensen2011a). Cost-effectiveness of multidisciplinary rehabilitation programmes has been found satisfactory (Jensen et al., Reference Jensen, Busch, Bodin, Hagberg, Nygren and Bergstrom2009; Lin et al., Reference Lin, Haas, Maher, Machado and Van Tulder2011). The evidence is based on mixed populations from both specialised and primary care settings.

Cross-country differences in national regulations on economical compensation for back pain seem to contribute to differences in RTW rate, while health, medical interventions and patients’ characteristic are reported as less important (Anema et al., Reference Anema, Schellart, Cassidy, Loisel, Veerman and Van Der Beek2009). European countries have varying levels of workplace health and safety provisions, which may influence work environment and the impact of adverse working conditions on health (Bambra et al., Reference Bambra, Lunau, Van Der Wel, Eikemo and Dragano2014). In Sweden, employers by law have an extensive responsibility for work environment (The Work Environment Act) in order to provide employees with safe work conditions. Employers also compensate for the first 14 days of sick leave.

In order to promote work ability, the Swedish Government implemented a national programme of evidence-based rehabilitation in primary care in 2009 (Regions). The intention with the national rehabilitation programme was to promote work ability, reduce sick leave and the risk of sick leave and increase RTW for patients with long-lasting (>3 months) MSP diagnosis and mild-to-moderate mental disorders in working age. Patients with MSP diagnoses, with ongoing pain-related sick leave or at risk of sick leave were to be offered MMR (Regions). The implementation posted many challenges concerning remittance and competence skill development (Brämberg et al., Reference Brämberg, Klinga, Jensen, Busch, Bergström, Brommels and Hansson2015). There was an intention to evaluate goal achievement, but there were no specific guidelines for the design of controlled follow-up. In the programme, there were no instructions to include workplace interventions, for example, contact with the employer, something that in studies have been found to have effect on RTW (Williams et al., Reference Williams, Westmorland, Lin, Schmuck and Creen2007; Kuoppala et al., Reference Kuoppala, Lamminpaa and Husman2008). Economic incentives for primary care centres to provide MMR rehabilitation were introduced. The Swedish Government initially compensated the county councils with 45 000 SEK (4791 EUR) per treated patient. There were some prerequisites, for example, that MMR should involve several professions, such as physicians, physiotherapists, psychologists and occupational therapists, and that MMR should primarily be provided as group treatment. MMR should include medical treatment, physiotherapy, cognitive behavioural therapy and patient education. Furthermore, MMR according to the programme required full- or part-time attendance over four to eight weeks.

The difficulties encountered in implementation and the problems faced when evaluating MMR might partly be explained by the fact that MMR was introduced in primary care after being developed within specialised, tertiary care where previous positive results had been reported (Jensen et al., Reference Jensen, Busch, Bodin, Hagberg, Nygren and Bergstrom2009; Norlund et al., Reference Norlund, Ropponen and Alexanderson2009; Busch et al., Reference Busch, Bodin, Bergström and Jensen2011a; Lin et al., Reference Lin, Haas, Maher, Machado and Van Tulder2011). MMR within the national programme of rehabilitation has been evaluated with special focus on action, implementation and development. The implementation pace was in general slow, partly due to uncertainty regarding new treatment modalities, organisational ambiguities and uncertainties concerning patient assortment as well as lack of knowledge how to promote work ability and RTW (Brämberg et al., Reference Brämberg, Klinga, Jensen, Busch, Bergström, Brommels and Hansson2015). However, other evaluations found that the personnel attitudes in primary care towards extended operations were positive in focusing psychosocial interventions for patients with MSP (Bakshi, Reference Bakshi, Brommels, Klinga, Bonnevier and Jensen2011; Busch et al., Reference Busch, Bonnevier, Hagberg, Lohela Karlsson, Bodin, Norlund and Jensen2011b). Much attention in the evaluations of MMR has been on patient’s outcomes (Stigmar et al., Reference Stigmar, Petersson, Joud and Grahn2013) and on process (Norlund et al., Reference Norlund, Ropponen and Alexanderson2009; Busch et al., Reference Busch, Bonnevier, Hagberg, Lohela Karlsson, Bodin, Norlund and Jensen2011b). There were no published randomised controlled trials (RCTs) evaluating the effect of MMR within primary care before the implementation of the national rehabilitation programme.

There have been attempts to design follow-up studies with reference groups retrieved from register data. The Swedish Social Insurance Inspectorate (ISF) analysed MMR outcomes in comparison with treatment as usual (ISF). They applied a matching approach using broad register data to identify reference pain patients not given MMR treatment. The ISF concluded that MMR was expensive and not cost-effective, mainly due to increased sick leave during and after MMR, compared to the treated as usual group. Busch et al. (Reference Busch, Bjork Bramberg, Hagberg, Bodin and Jensen2017) studied the effect of MMR on sick leave by applying a matching approach using broad register data to identify reference pain patients (Busch et al., Reference Busch, Bjork Bramberg, Hagberg, Bodin and Jensen2017). They found that MMR did not reduce sick leave compared to treatment as usual. However, this study included MMR both within specialised rehabilitation clinics and in primary care. In addition, a large proportion of the included patients were on disability pension at baseline and hence not representing the intended target group for MMR. An assumption behind a retrospective matching design is that there is a random distribution of MSP patients receiving MMR or not. However, referral to MMR has been found to be associated with caregiver and community-related factors (Sennehed et al., Reference Sennehed, Holmberg, Stigmar, Forsbrand, Petersson, Nyberg and Grahn2017). In summary, there is a lack of controlled trials and evaluations of MMR in primary care, especially for patients on shorter sick leave.

The aim of this study was to investigate the feasibility of identifying a well-defined treatment group and a comparable reference group in clinical register data for potential effect evaluation of MMR for MSP patients in primary care.

Materials and methods

Design

We performed a register-based longitudinal observational cohort study in primary care, with two-year follow-up of patients given MMR and a well-defined register-based reference group. This study examined the feasibility (Bowen et al., Reference Bowen, Kreuter, Spring, Cofta-Woerpel, Linnan, Weiner, Bakken, Kaplan, Squiers, Fabrizio and Fernandez2009) of identifying the two cohorts for an evaluation of the MMR programme. We used register data from the Population Register in Region Skåne, the Skåne Health Care Register (SHR), the Statistics Sweden, the Swedish Social Insurance Agency (MiDAS) and The National Board of Health and Welfare. We collected data from one year before baseline (start of treatment) to two years after baseline.

Study population

The study population was identified in SHR during the period 1 January 2010 to 31 December 2011. All patients of working age, 20–60 years, registered as having received MMR in Region Skåne were identified in the SHR covering all publicly tax-financed health care in Region Skåne. A reference cohort was identified in the same register, including patients in the same age span that had been registered with the same MSP diagnose codes during the same period.

We identified a cohort of 2140 MMR patients, with MSP diagnoses. Approximately one-third of the patients had incomplete treatment sessions of MMR or insufficient time for follow-up and were therefore excluded (Figure 1). We identified a reference cohort of 56 300 patients with the same MSP diagnoses. In order to limit the reference cohort to patients that probably had a need for more extensive rehabilitation, we set an inclusion criterion for patients in the reference cohort, namely that these patients should have at least one or more additional consultations in health care within three months due to the same diagnosis. Three-quarters of patients in the original reference cohort did not have an additional consultation due to the same diagnose within three months and were hence excluded. In a next step, patients with no sick leave, sick leave ≥360 days and those already granted a disability pension more than 180 days the year before baseline were excluded in both the MMR cohort and the reference cohort. Non-eligible patients were excluded before baseline, and no further exclusions were made during analysis (Figure 1). The final study group consisted of 603 MMR patients and 2874 reference patients, and all study participants had been on registered sick leave at least one day up to 359 days the year before baseline (Figure 1).

Figure 1. Flow chart of selection of the cohorts during 2010–2011, in age 20–60 years with MSP diagnoses

  1. 1 Multimodal rehabilitation cohort.

  2. 2 Reference cohort.

  3. 3 MMR group inclusion criteria: in a register 20100101-20111231, age 20–60 years, diagnostic code according to the National Rehabilitation Program, no withdrawal, residence in Region Skåne, or deceased through 2013, no reused personal code number. At least six treatment sessions within MMR treatment period. Minimum 6 and maximum 26 weeks as MMR treatment period. At least six treatment sessions over a period of maximum six weeks. Over this six-week period at least one treatment session during four weeks in the six-week period. Either no visit or at most one visit to the rehabilitation medicine centre with a registered pain diagnosis (in accordance with the National Rehabilitation Program) over the years 2008–2012.

  4. 4 Reference group inclusion criteria: age 20–60 years, in Region Skåne medical record with no withdrawal, any registered diagnostic code within the definition from the National Rehabilitation Program as main diagnose within Hälsovalet during 20100101-20111231, code registered at any office visit, within defined care area (primary care, psychiatric or somatic care), outpatient care, diagnose registered by physician, physiotherapist, psychologist or team, residency in Region Skåne or deceased, no reused personal code number. Either no visit or at most one visit to the rehabilitation medicine centre with a registered pain diagnosis (in accordance with the National Rehabilitation Program) over the years 2008–2012. After inclusion, at least one or more office visits within three months (92 days) that fulfil the same criteria regarding type and setting for MMR diagnose.

Studied variables

Age, sex, diagnoses and health care consultations were available from the SHR. Drug use measured as defined daily dose (DDD) was received from the National Board of Health and Welfare. Education, profession, net income and employment status were obtained from the Statistics Sweden (SCB). Sick leave data were received from MiDAS.

The diagnoses were registered according to the Swedish translation of International Classification of Diseases and Related Health Problems (ICD) 10 system, chapter XIII (WHO). Diagnoses were categorised into four groups; myalgia and pain (M245, M542, M791, M799P, R52, M840P) neck/shoulder pain (M50, M530-531, M750-755, M759P, S134, T918A), back pain (M51, M533, M543-546, M549P, M431) and rheumatism (M790). Number of contacts/year with physicians in health care was reported as mean values. Drug uses as DDD with regard to pain, sleep and depression medications were reported as mean values. Educational level was categorised as low (<10 years education), medium (10–12 years education) and high (>12 years education). Profession area was categorised into four groups; white collar (managers, senior officials, where specific education is required), pink collar (care, office, service, sale), blue collar (industry, craftsmen, agriculture, forestry, fishing) and low level (cleaning, assistants, where specific training is not required) (Yang et al., Reference Yang, Kim, Choi and Yi2016). Net income/year (income after taxes) was reported as mean values.

Sick leave was assessed as total number of sick leave days (≥15 sick leave days 0–24 months after baseline). Sick leave days were delivered as whole days and not possible to transform to partial days. In Sweden, the first 14 days of sick leave are paid by the employer and were hence not possible to retrieve from the registry. A sick leave ≥15 day is economically compensated by the Swedish Social Insurance Agency and in the registry.

Statistical analyses

Baseline data were compared with one- and two-year follow-up data within the MMR group and the reference group, respectively. For the descriptive statistics, we used Fisher’s exact test and Chi-square test for proportions and t-test for continuous variables. The distribution of the variables was not normally distributed, especially the number of sick leave days at baseline and one and two years after baseline follow-up. Based on this, we used non-parametric statistics to compare baseline data and one- and two-year follow-up data, the Wilcoxon’s signed rank test and related-samples Friedman’s two-way analysis of variance by ranks. SPSS for Windows version 24 was used for all statistical analyses. P-values <0.05 were considered significant.

Findings

There were major differences between the MMR and the reference group in socio-economic and health measures at baseline (Table 1). The MMR patients were to a greater extent female compared to the reference group (P < 0.001). Diagnoses such as myalgia and pain were more prevalent in the MMR group (37% versus 23%, P < 0.001), and the MMR patients had more frequent contacts with physicians than the reference group (mean 16 contacts versus 9 contacts, P < 0.001). Drug use targeting pain, sleep and depression was higher in the MMR group than in the reference group. Also, the number of sick leave days during the year prior to baseline was higher in the MMR group than in the reference group (mean 118 days versus 50 days, P < 0.001) (Table 1). In summary, the differences in baseline characteristics between the MMR group and the reference group were significant for all studied variables except for age and education.

Table 1. Baseline characteristics of participants in the MMR group and in the reference group

a t-test.

b Fisher’s exact test.

c Chi-square test.

d The year before baseline.

Application of the described inclusion and exclusion criteria in order to define as relevant and comparable groups as possible resulted in that the finally defined MMR group (n = 603) was 28% of the entire registered MMR cohort (n = 2140). The final reference group (n = 2874) constituted only 5% of the initial registered reference cohort (n = 56 300). The MMR group was limited due to a large number not having a complete treatment or not fulfilling the sick leave criteria. As many as 717 patients in the initial cohort had no registered sick leave the year prior to treatment. For the reference cohort, the majority did not fulfil the criteria of having more than one health care contact due to the identified MSP diagnose within three months and among those who did fulfil this criterion most did not have registered sick leave. We also tried an even stricter sick leave criterion by limiting sick leave one year before baseline to 91–180 days and excluding all patients with any disability pension the year before inclusion in order to identify a group that theoretically would be most relevant for MMR treatment with the goal of faster RTW. However, this rendered the remaining study groups too small for meaningful analysis, the MMR group 6% (n = 130) and the reference group 0.3% (n = 213) of the original cohorts, respectively.

Follow-up MMR group

Number of sick leave days decreased significantly in the MMR group (118 days to 102 days per year, P < 0.001) from one year before baseline to two years after (Table 2 and Figure 2). At two-year follow-up, 26% of the MMR patients were on sick leave lasting more than 180 days (Table 2). The proportion with no sick leave during a whole year increased from 14% one year after to 42% two years after baseline (Table 2). At baseline, 89% of the MMR patients were employed, and the proportion decreased to 78%, after two years (Table 2).

Table 2. Sick leave (≥15 days net) and employment status over time for the MMR group and for the reference group

Related-samples Friedman’s two-way analysis of variance by ranks:

a Results one year before compared with results one years after.

b Results one year before compared with results two years after.

c Results one year after compared with results two years after.

Wilcoxon signed-ranks test:

d Results one year after compared with results two years after.

e Results one year before compared with results one years after.

Figure 2. Number of sick leave days (over three months/a quarter), before and after baseline, in the MMR group and the reference group

Follow-up reference group

Number of sick leave days decreased significantly in the reference group (50 days to 42 days per year, P < 0.001) from one year before baseline to two years after (Table 2 and Figure 2). The sick leave pattern was very similar to the MMR group although the number of sick leave days was lower over the entire period (Figure 2). At two-year follow-up, 7% were on sick leave for more than 180 days (Table 2). The proportion with no sick leave during a whole year increased from 17% one year after to 56% two years after baseline (Table 2). At baseline, 95% of the reference group were employed and the proportion was lower after two years (86%) (Table 2).

In summary, the proportion of patients on sick leave in the MMR group and in the reference group followed the same pattern with a peak the months prior to and direct following baseline. However, the MMR group had a higher proportion on sick leave over the whole study period.

Discussion

We found it not feasible to identify two comparable groups for a fair effect evaluation due to significant selection bias. Despite an ambitious attempt to identify a comparable register-based reference group, there were significant socio-economic and health differences at baseline between the MMR group and the reference group, with the MMR group having lower income and higher morbidity. The MMR group had more sick leave days, but the pattern over time from one year before baseline and over two years of follow-up were similar for both groups.

A major strength of this study was the possibility to retrieve broad registry data with full coverage and follow-up of the patient’s over several years. In our attempt to achieve comparability between the groups, we considered it vital that patients in the MMR group and in the reference group had similar disease burden. Therefore, we used criteria to identify a reference group of patients with similar morbidity as the MMR group regarding diagnoses, health care contacts, extent of sick leave and disability pension. Despite the use of strict inclusion and exclusion criteria in order to control these conditions, the MMR group had higher morbidity compared to the reference group at baseline, represented by more complex MSP diagnoses, higher number of contacts with physicians, higher drug use and higher number of sick leave days. There were also major baseline differences between the groups in gender, profession areas and net income. Gender and age (Laisne et al., Reference Laisne, Lecomte and Corbiere2013), education and income (Streibelt and Egner, Reference Streibelt and Egner2013), profession (Hubertsson et al., Reference Hubertsson, Turkiewicz, Petersson and Englund2017), drug use (Rinaldo and Selander, Reference Rinaldo and Selander2016) and history of sick leave (Dekkers-Sanchez et al., Reference Dekkers-Sanchez, Hoving, Sluiter and Frings-Dresen2008, Hubertsson et al., Reference Hubertsson, Englund, Hallgarde, Lidwall, Lofvendahl and Petersson2014) are all key variables in relation to sickness development and to successful RTW and need to be taken into account in an effect analysis. The recognised selection bias indicates lack of feasibility for the identification of a comparable reference group for effect evaluation of MMR in primary care based on observational clinical register data. It is emphasised by Craig et al. that the implementation of complex interventions in primary care needs to follow the rules of Medical Research Council on evaluating complex interventions (Craig et al., Reference Craig, Martin, Browne, Simpson, Wight, Robling, Moore, Hallingberg, Segrott, Turley, Murphy and Moore2018).

A limitation of our study is the relatively small study population. Our ambition was to include patient cohorts from 2010 to 2012 and follow-up data up to three years after baseline. The last delivery of data was from autumn 2016, but despite this, the analysis was limited by missing sick leave data. Due to the delay in delivery of data and due to a substantial proportion missing data for the follow-up years for patients included with baseline in 2012, we restricted the analyses to baseline inclusion during 2010–2011 with follow-up over two years. The study was restricted to Region Skåne since there was a comprehensive programme for register data for all MMR treatments in the region. The sick leave data received from the Swedish Social Insurance Agency were delivered as whole days and did not include part-time sick leave days which could be considered as a limitation. It must, however, be emphasised that this was not the purpose of our study.

Using register diagnoses for inclusion of referents is problematic since diagnoses are wide entities and are affected by physicians’ assessments (Mallen et al., Reference Mallen, Thomas, Belcher, Rathod, Croft and Peat2013). Patients registered with the same MSP diagnosis may differ in vital areas associated with work ability and sick leave. One example is the diagnosis lumbago, M545 (ICD-10), which cover everything from a first episode of mild discomfort with high work ability and no sick leave days to a period of severe pain with largely decreased work ability and a large number of sick leave days. In this study, only 28% and 5%, respectively, of the original entire cohorts fulfilled inclusion criteria. This illustrates the difficulties inherent when trying to identify relevant reference groups, based on retrospective register data for this patient population. Consequently, it questions the validity of retrospective comparisons between MSP patient groups treated with MMR and reference groups and calls for randomised study design. The national implementation of MMR in primary care can be regarded as a natural experiment, and in lack of RCTs it is worth trying to evaluate observational register data. An alternative method for evaluation might have been limiting implementation to specific areas (county councils) and kept other areas as reference in a national follow-up.

We considered a matching procedure with propensity score as an alternative method for creating a retrospective control group. However, the same difficulties in achieving enough number of reference patients can be anticipated depending on how strict matching criteria are needed in order to limit bias. From a retrospective research perspective, it is desirable that patients with similar diagnoses are referred to MMR or other treatments randomly, but from a clinical perspective we know that this is not the case. Complex clinical and practical assessments are made before decisions to refer to MMR. Referrals to MMR are also associated with caregiver and community-related factors (Sennehed et al., Reference Sennehed, Holmberg, Stigmar, Forsbrand, Petersson, Nyberg and Grahn2017). The clinical considerations made in primary care before referral to MMR are multifaceted and complex and contributes to bias by indication. Important variables such as functional level, activity level and motivation for change that should be controlled in a prospective randomisation procedure cannot be controlled in retrospect irrespective of applied method (Grahn et al., Reference Grahn, Borgquist and Ekdahl2004). Finally, another option for evaluation can be to let each individual be its own control over time. This may enhance understanding of treatment mechanisms and individual effects and allow comparison between treatment subgroups. Such a design may analyse the effect of MMR in those who received it, following each person and processes (Rivano Fischer et al., Reference Rivano Fischer, Persson, Stalnacke, Schult and Lofgren2019). However, without reference group, treatment effects cannot be fully assessed.

The number of sick leave days during the year before baseline varied significantly, and the MMR group was to a greater extent on sick leave in comparison with the reference group. Still, the proportion of patients with no sick leave days increased successively in both groups two years after baseline, an indicator that the treatment effect in the MMR group was similar and comparable to the reference group. The development of sick leave over time for the MMR patients if they had not received the MMR treatment is unknown. Sick leave is not a major problem for most patients with MSP consulting primary care and it is well known that about 80–90% of those with back pain recover spontaneously in about six weeks. Many do not need more comprehensive rehabilitation efforts within primary care to maintain their work ability (Waddell, Reference Waddell1987; Waddell and Burton, Reference Waddell and Burton2005). It is, therefore, important to allocate patients to the best possible treatment at an optimal time and in the case of RTW to take the number of sick leave days into account when planning treatment (Shiri et al., Reference Shiri, Kausto, Martimo, Kaila-Kangas, Takala and Viikari-Juntura2013; Stigmar et al., Reference Stigmar, Petersson, Joud and Grahn2013). In this study, 25% in the MMR group and 7% in the reference group were on sick leave for more than 180 days one year before baseline. This indicates that the MMR group needed rehabilitation to a greater extent compared to the reference group and is considered a major selection bias remaining despite efforts to create comparable study groups. The sick leave criterion 1–359 of sick leave the year prior to baseline reduced the study population in both groups considerably. Only a small proportion of the study population had a granted disability pension, at most 180 days, the year before inclusion.

The MMR group differed significantly at baseline from the reference group regarding gender, profession and morbidity, well-known factors that may affect RTW and might partly explain some of the obstacles for a successful treatment (Nyberg et al., Reference Nyberg, Novo and Sjolund2014; Kvam and Eide, Reference Kvam and Eide2015; Cancelliere et al., Reference Cancelliere, Donovan, Stochkendahl, Biscardi, Ammendolia, Myburgh and Cassidy2016). Myalgia and pain diagnoses were overrepresented in the MMR group and these unspecified diagnoses are well known as risk factors for failed RTW (Cancelliere et al., Reference Cancelliere, Donovan, Stochkendahl, Biscardi, Ammendolia, Myburgh and Cassidy2016; Rinaldo and Selander, Reference Rinaldo and Selander2016). Previous studies confirm the significance of important factors for RTW, such as workplace physical demands (Steenstra et al., Reference Steenstra, Munhall, Irvin, Oranye, Passmore, Van Eerd, Mahood and Hogg-Johnson2016), social class and educational level (Ropponen et al., Reference Ropponen, Silventoinen, Svedberg, Alexanderson, Koskenvuo, Huunan-Seppälä, Koskenvuo and Kaprio2011), psychosocial factors (Laisne et al., Reference Laisne, Lecomte and Corbiere2013) and income before treatment (Streibelt and Egner, Reference Streibelt and Egner2013). Furthermore, a recent study indicates that socio-economic status may influence referring to MMR (Sennehed et al., Reference Sennehed, Holmberg, Stigmar, Forsbrand, Petersson, Nyberg and Grahn2017). In the initial cohorts (MMR n = 2140 and reference n = 56 300), the proportion of patients with disability pension one year before baseline were 22% in the MMR cohort and 10% in the reference cohort. This is well in line with results presented by Busch et al. (Reference Busch, Bjork Bramberg, Hagberg, Bodin and Jensen2017) where a large proportion of the MMR patients showed generally worse status and a large proportion of included MMR patients were on disability pension. There was no information about the treated as usual group’s morbidity or need for rehabilitation (Busch et al., Reference Busch, Bjork Bramberg, Hagberg, Bodin and Jensen2017). In our study, from the initial reference cohort, a large proportion of patients were excluded since they did not have a second health care consultation within three months due to the same MSP diagnosis. This exclusion criterion was set as an indicator of the severity of the patient’s MSP problems in order to increase the probability that the reference group had a real need for rehabilitation. We restricted the age of participants to 20–60 years in order to encompass work age in Sweden.

This study illustrates the difficulties in retrospective evaluation of medical treatments and rehabilitation. To select patients for more extensive rehabilitation, better methods are needed. Prognostic screening, as the STarT Back Screening Tool, a triage model for early identification by screening patients ‘at risk’ is one example suggested in primary care enhance the decision-making process and has shown positive results both in terms of patients’ improved health and cost-effectiveness (Hill et al., Reference Hill, Whitehurst, Lewis, Bryan, Dunn, Foster, Konstantinou, Main, Mason, Somerville, Sowden, Vohora and Hay2011; Forsbrand et al., Reference Forsbrand, Grahn, Hill, Petersson, Sennehed and Stigmar2017). In addition, patients’ motivation is a strong predictor for treatment results, especially for this group with pronounced pain problems (Grahn et al., Reference Grahn, Borgquist and Ekdahl2004) and needs to be taken into consideration in study design. It is important to realise that rehabilitation being conducted only within the framework of health care services cannot create new suitable employments or customise employment for patients with limited work ability in their current work due to health problems. Workplace interventions, for example, contact between health care professionals and employers have been found to have effect on RTW (Williams et al., Reference Williams, Westmorland, Lin, Schmuck and Creen2007; Kuoppala et al., Reference Kuoppala, Lamminpaa and Husman2008; Sennehed et al., Reference Sennehed, Holmberg, Axen, Stigmar, Forsbrand, Petersson and Grahn2018). More initiatives and studies involving labour market, workplace, employers and rules for conversion of work and remuneration are needed.

Conclusion

We conclude that it was not feasible to identify a comparable reference group for effect evaluation of MMR in primary care based on clinical register data. Despite an ambitious attempt to limit selection bias, significant baseline differences in socio-economic and health status were present. In absence of some form of randomised trials, treatment effects of MMR cannot be sufficiently evaluated in primary care.

Acknowledgements

Region Skåne supported retrieving patient data. We send our gratitude to data manager Pernilla Nilsson, ERC South, Region Skåne, for management of register data and also to senior lecturer, PhD, Anna Lindgren, Centre for Mathematical Sciences, Lund University, Lund, Sweden, for supporting data analyses and interpretation. Adam Post preformed proofreading of the manuscript.

Authors’ contributions

CPS, SH, BG, KS and IP were responsible for the study design, data analyses and interpretation. CPS collected data and drafted the manuscript. CPS, SH and BG prepared and validated data. IP, AN, MF and MRF took part in the study design and interpretation of data. All authors read and approved the final version of the manuscript.

Financial Support

Research funding within the PhD studies of CPS, Lund University, Lund, Sweden and Region Skåne, Sweden.

Conflicts of interest

The authors declare no conflicts of interest.

Ethical Standards

The study was approved by the Regional Ethical Review Board in Lund, EPN Dnr 2014/290, 11 June 2014.

Availability of data and materials

Data are available from the corresponding author on reasonable request.

Consent for publication

Not applicable.

References

Alexanderson, K and Norlund, A (2004) Swedish council on technology assessment in Health Care (SBU). Chapter 1. Aim, background, key concepts, regulations, and current statistics. Scandinavian Journal of Public Health Supplement 63, 1230.CrossRefGoogle ScholarPubMed
Anema, JR, Schellart, AJM, Cassidy, JD, Loisel, P, Veerman, TJ and Van Der Beek, AJ (2009) Can cross country differences in return-to-work after chronic occupational back pain be explained? an exploratory analysis on disability policies in a six Country Cohort Study. Journal of Occupational Rehabilitation 19, 419426.CrossRefGoogle Scholar
Bakshi, A HJL, Brommels, M, Klinga, C, Bonnevier, H and Jensen, IB (2011) En processutvärdering av implementeringen av den nationella rehabiliteringsgarantin. Slutrapport del II. (A process evaluation of the implementation of the national rehabilitation guarantee). In Swedish.: Enheten för implementerings- och interventionsforskning. Stockholm: Institutet för miljömedicin samt Medical management Centrum, Institutionen för lärande, information och etik, Karolinska Institutet.Google Scholar
Bambra, C, Lunau, T, Van Der Wel, KA, Eikemo, TA and Dragano, N (2014) Work, health and welfare: the association between working conditions, welfare states, and self-reported general health in Europe. International Journal of Health Services 44, 113–136.CrossRefGoogle Scholar
Bevan, S, Quadrello, T, Mcgee, R, Mahdon, M, Vavrovsky, A and Barham, L (2009) Fit for work? Musculoskeletal disorders in the European workforce. Thed Work Foundation. Retrieved Accessed 8 June 2016 from http://www.fitforworkeurope.eu/Website-Documents/Fit%20for%20Work%20pan-European%20report.pdf.Google Scholar
Bowen, DJ, Kreuter, M, Spring, B, Cofta-Woerpel, L, Linnan, L, Weiner, D, Bakken, S, Kaplan, CP, Squiers, L, Fabrizio, C and Fernandez, M (2009) How we design feasibility studies. American Journal of Preventive Medicine 36, 452–457.CrossRefGoogle ScholarPubMed
Brämberg, EB, Klinga, C, Jensen, I, Busch, H, Bergström, G, Brommels, M and Hansson, J (2015) Implementation of evidence-based rehabilitation for non-specific back pain and common mental health problems: a process evaluation of a nationwide initiative. BMC Health Services Research 15, 79.CrossRefGoogle ScholarPubMed
Busch, H, Bjork Bramberg, E, Hagberg, J, Bodin, L and Jensen, I (2017) The effects of multimodal rehabilitation on pain-related sickness absence – an observational study. Disability and Rehabilitation 40, 16461653.CrossRefGoogle ScholarPubMed
Busch, H, Bodin, L, Bergström, G and Jensen, IB (2011a) Patterns of sickness absence a decade after pain-related multidisciplinary rehabilitation. Pain 152, 17271733.CrossRefGoogle ScholarPubMed
Busch, H, Bonnevier, H, Hagberg, J, Lohela Karlsson, M, Bodin, L, Norlund, A and Jensen, I (2011b) En nationell utvärdering av rehabiliteringsgarantins effekter på sjukfrånvaro och hälsa, Slutrapport del I. (A national evaluation of the rehabilitation guarantee effects on sick leave and health). In Swedish.: Enheten för interventions- och implementeringsforskning. Stockholm: Institutet för miljömedicin (IMM), Karolinska Institutet.Google Scholar
Cancelliere, C, Donovan, J, Stochkendahl, MJ, Biscardi, M, Ammendolia, C, Myburgh, C and Cassidy, JD (2016) Factors affecting return to work after injury or illness: best evidence synthesis of systematic reviews. Chiropractic & Manual Therapies 24, 32.CrossRefGoogle ScholarPubMed
Craig, P, Martin, A, Browne, S, Simpson, SA, Wight, D, Robling, M, Moore, G, Hallingberg, B, Segrott, J, Turley, R, Murphy, S and Moore, L (2018) Development of guidance for feasibility studies to decide whether and how to proceed to full-scale evaluation of complex public health interventions: a systematic review. Lancet 392, 7.CrossRefGoogle Scholar
Dekkers-Sanchez, PM, Hoving, JL, Sluiter, JK and Frings-Dresen, MH (2008) Factors associated with long-term sick leave in sick-listed employees: a systematic review. Occupational and Environmental Medicine 65, 153157.CrossRefGoogle ScholarPubMed
Forsbrand, M, Grahn, B, Hill, JC, Petersson, IF, Sennehed, CP and Stigmar, K (2017) Comparison of the Swedish STarT Back Screening Tool and the Short Form of the Orebro Musculoskeletal Pain Screening Questionnaire in patients with acute or subacute back and neck pain. BMC Musculoskeletal Disorders 18, 89.CrossRefGoogle ScholarPubMed
Gerdle, B, Bjork, J, Coster, L, Henriksson, K, Henriksson, C and Bengtsson, A (2008) Prevalence of widespread pain and associations with work status: a population study. BMC Musculoskeletal Disorders 9, 102.CrossRefGoogle ScholarPubMed
Grahn, BE, Borgquist, LA and Ekdahl, CS (2004) Rehabilitation benefits highly motivated patients: a six-year prospective cost-effectiveness study. International Journal of Technology Assessment in Health Care 20, 214–221.CrossRefGoogle ScholarPubMed
Gustavsson, A, Bjorkman, J, Ljungcrantz, C, Rhodin, A, Rivano-Fischer, M, Sjolund, KF and Mannheimer, C (2012) Socio-economic burden of patients with a diagnosis related to chronic pain--register data of 840,000 Swedish patients. European Journal of Pain 16, 289–299.CrossRefGoogle ScholarPubMed
Guzman, J, Esmail, R, Karjalainen, K, Malmivaara, A, Irvin, E and Bombardier, C (2001) Multidisciplinary rehabilitation for chronic low back pain: systematic review. BMJ 322, 15111516.CrossRefGoogle ScholarPubMed
Hill, JC, Whitehurst, DG, Lewis, M, Bryan, S, Dunn, KM, Foster, NE, Konstantinou, K, Main, CJ, Mason, E, Somerville, S, Sowden, G, Vohora, K and Hay, EM (2011) Comparison of stratified primary care management for low back pain with current best practice (STarT Back): a randomised controlled trial. Lancet 378, 1560–71.CrossRefGoogle ScholarPubMed
Hubertsson, J, Englund, M, Hallgarde, U, Lidwall, U, Lofvendahl, S and Petersson, IF (2014) Sick leave patterns in common musculoskeletal disorders--a study of doctor prescribed sick leave. BMC Musculoskeletal Disorders 15, 176.CrossRefGoogle ScholarPubMed
Hubertsson, J, Turkiewicz, A, Petersson, IF and Englund, M (2017) Understanding occupation, sick leave, and disability pension due to knee and hip osteoarthritis from a sex perspective. Arthritis Care Res (Hoboken) 69, 226–33.CrossRefGoogle ScholarPubMed
Isf TSSII. The Effects of the Swedish Rehabilitation Guarantee on Health and Sickness Absence, Report 2014:12. Retrieved 1 March 2017 from http://62.13.72.13/fb/ISF/ISF%202014-12/HTM/index.html.Google Scholar
Jensen, IB, Busch, H, Bodin, L, Hagberg, J, Nygren, A and Bergstrom, G (2009) Cost effectiveness of two rehabilitation programmes for neck and back pain patients: a seven year follow-up. Pain 142, 202208.CrossRefGoogle ScholarPubMed
Jordan, KP, Kadam, UT, Hayward, R, Porcheret, M, Young, C and Croft, P (2010) Annual consultation prevalence of regional musculoskeletal problems in primary care: an observational study. BMC Musculoskeletal Disorders 11, 144.CrossRefGoogle Scholar
Kamper, SJ, Apeldoorn, AT, Chiarotto, A, Smeets, RJ, Ostelo, RW, Guzman, J and Van Tulder, MW (2015) Multidisciplinary biopsychosocial rehabilitation for chronic low back pain: cochrane systematic review and meta-analysis. BMJ 350, h444.CrossRefGoogle ScholarPubMed
Kinge, JM, Knudsen, AK, Skirbekk, V and Vollset, SE (2015) Musculoskeletal disorders in Norway: prevalence of chronicity and use of primary and specialist health care services. BMC Musculoskeletal Disorders 16, 75.CrossRefGoogle ScholarPubMed
Kuoppala, J, Lamminpaa, A and Husman, P (2008) Work health promotion, job well-being, and sickness absences--a systematic review and meta-analysis. Journal of Occupational and Environmental Medicine 50, 12161227.CrossRefGoogle ScholarPubMed
Kvam, L and Eide, AH (2015) Gender differences in the importance of participation associated with injured workers/persons perceived barriers to returning to work in the context of vocational rehabilitation. Disability and Rehabilitation 37, 7885.CrossRefGoogle ScholarPubMed
Laisne, F, Lecomte, C and Corbiere, M (2013) Biopsychosocial determinants of work outcomes of workers with occupational injuries receiving compensation: a prospective study. Work 44, 117132.CrossRefGoogle ScholarPubMed
Liddle, SD, Gracey, JH and Baxter, GD (2007) Advice for the management of low back pain: a systematic review of randomised controlled trials. Manual Therapy 12, 310327.CrossRefGoogle ScholarPubMed
Lin, CW, Haas, M, Maher, CG, Machado, LA and Van Tulder, MW (2011) Cost-effectiveness of guideline-endorsed treatments for low back pain: a systematic review. European Spine Journal 20, 10241038.CrossRefGoogle ScholarPubMed
Mallen, CD, Thomas, E, Belcher, J, Rathod, T, Croft, P and Peat, G (2013) Point-of-care prognosis for common musculoskeletal pain in older adults. JAMA Internal Medicine 173, 11191125.CrossRefGoogle ScholarPubMed
Norlund, A, Ropponen, A and Alexanderson, K (2009) Multidisciplinary interventions: review of studies of return to work after rehabilitation for low back pain. Journal of Rehabilitation Medicine 41, 115121.CrossRefGoogle ScholarPubMed
Nyberg, VE, Novo, M and Sjolund, BH (2014) Changes in multidimensional pain inventory profile after a pain rehabilitation programme indicate the risk of receiving sick leave benefits one year later. Journal of Rehabilitation Medicine 46, 10061013.CrossRefGoogle ScholarPubMed
Rinaldo, U and Selander, J (2016) Return to work after vocational rehabilitation for sick-listed workers with long-term back, neck and shoulder problems: a follow-up study of factors involved. Work 55, 115131.CrossRefGoogle ScholarPubMed
Rivano Fischer, M, Persson, EB, Stalnacke, BM, Schult, ML and Lofgren, M (2019) Return to work after interdisciplinary pain rehabilitation: one- and two-year follow-up based on the Swedish Quality Registry for Pain rehabilitation. Journal of Rehabilitation Medicine 51, 281289.CrossRefGoogle ScholarPubMed
Ropponen, A, Silventoinen, K, Svedberg, P, Alexanderson, K, Koskenvuo, K, Huunan-Seppälä, A, Koskenvuo, M and Kaprio, J (2011) Health-related risk factors for disability pensions due to musculoskeletal diagnoses: a 30-year Finnish twin cohort study. Scandinavian Journal of Public Health 39, 839848.CrossRefGoogle ScholarPubMed
Sennehed, CP, Holmberg, S, Axen, I, Stigmar, K, Forsbrand, M, Petersson, IF and Grahn, B (2018) Early workplace dialogue in physiotherapy practice improved work ability at one-year follow-up – workup a randomised controlled trial in primary care. Pain 159, 14561464.CrossRefGoogle Scholar
Sennehed, CP, Holmberg, S, Stigmar, K, Forsbrand, M, Petersson, IF, Nyberg, A and Grahn, B (2017) Referring to multimodal rehabilitation for patients with musculoskeletal disorders – a register study in primary health care. BMC Health Services Research 17, 15.CrossRefGoogle ScholarPubMed
Shiri, R, Kausto, J, Martimo, KP, Kaila-Kangas, L, Takala, EP and Viikari-Juntura, E (2013) Health-related effects of early part-time sick leave due to musculoskeletal disorders: a randomized controlled trial. Scandinavian Journal of Work, Environment & Health 39, 3745.CrossRefGoogle ScholarPubMed
Steenstra, IA, Munhall, C, Irvin, E, Oranye, N, Passmore, S, Van Eerd, D, Mahood, Q and Hogg-Johnson, S (2016) Systematic review of prognostic factors for return to work in workers with sub acute and chronic low back pain. Journal of Occupational Rehabilitation 27, 369381.CrossRefGoogle Scholar
Stigmar, K, Petersson, I, Joud, A and Grahn, B (2013) Promoting work ability in a structured national rehabilitation program in patients with musculoskeletal disorders: outcomes and predictors in a prospective cohort study. BMC Musculoskeletal Disorders 14, 57.CrossRefGoogle Scholar
Streibelt, M and Egner, U (2013) A systematic review of the predictors of return to work following vocational retraining. Rehabilitation (Stuttg) 52, 111118.Google ScholarPubMed
Swedish Agency for Health Technology Assessment and Assessment of Social Services SS. Preventiva insatser vid akut smärta från rygg och nacke. Effekter av fysisk träning, manuell behandling och beteendepåpverkande åtgärder. (Acute neck and back pain:preventive interventions. Effects of physical training, manual treatment and cognitive behavioral interventions). In Swedish. Retrieved 17 January 2018 from http://www.sbu.se/contentassets/fc9b009a51834b69b2dbc25f80fef475/prevention_smarta_160607.pdf.Google Scholar
Vos, T, Flaxman, AD, Naghavi, M, Lozano, R, Michaud, C, Ezzati, M, Shibuya, K, Salomon, JA, Abdalla, S, Aboyans, V, Abraham, J, Ackerman, I, Aggarwal, R, Ahn, SY, Ali, MK, Alvarado, M, Anderson, HR, Anderson, LM, Andrews, KG, Atkinson, C, Baddour, LM, Bahalim, AN, Barker-Collo, S, Barrero, LH, Bartels, DH, Basáñez, MG, Baxter, A, Bell, ML, Benjamin, EJ, Bennett, D, Bernabé, E, Bhalla, K, Bhandari, B, Bikbov, B, Bin Abdulhak, A, Birbeck, G, Black, JA, Blencowe, H, Blore, JD, Blyth, F, Bolliger, I, Bonaventure, A, Boufous, S, Bourne, R, Boussinesq, M, Braithwaite, T, Brayne, C, Bridgett, L, Brooker, S, Brooks, P, Brugha, TS, Bryan-Hancock, C, Bucello, C, Buchbinder, R, Buckle, G, Budke, CM, Burch, M, Burney, P, Burstein, R, Calabria, B, Campbell, B, Canter, CE, Carabin, H, Carapetis, J, Carmona, L, Cella, C, Charlson, F, Chen, H, Cheng, AT, Chou, D, Chugh, SS, Coffeng, LE, Colan, SD, Colquhoun, S, Colson, KE, Condon, J, Connor, MD, Cooper, LT, Corriere, M, Cortinovis, M, de Vaccaro, KC, Couser, W, Cowie, BC, Criqui, MH, Cross, M, Dabhadkar, KC, Dahiya, M, Dahodwala, N, Damsere-Derry, J, Danaei, G, Davis, A, De Leo, D, Degenhardt, L, Dellavalle, R, Delossantos, A, Denenberg, J, Derrett, S, Des Jarlais, DC, Dharmaratne, SD, Dherani, M, Diaz-Torne, C, Dolk, H, Dorsey, ER, Driscoll, T, Duber, H, Ebel, B, Edmond, K, Elbaz, A, Ali, SE, Erskine, H, Erwin, PJ, Espindola, P, Ewoigbokhan, SE, Farzadfar, F, Feigin, V, Felson, DT, Ferrari, A, Ferri, CP, Fèvre, EM, Finucane, MM, Flaxman, S, Flood, L, Foreman, K, Forouzanfar, MH, Fowkes, FG, Franklin, R, Fransen, M, Freeman, MK, Gabbe, BJ, Gabriel, SE, Gakidou, E, Ganatra, HA, Garcia, B, Gaspari, F, Gillum, RF, Gmel, G, Gosselin, R, Grainger, R, Groeger, J, Guillemin, F, Gunnell, D, Gupta, R, Haagsma, J, Hagan, H, Halasa, YA, Hall, W, Haring, D, Haro, JM, Harrison, JE, Havmoeller, R, Hay, RJ, Higashi, H, Hill, C, Hoen, B, Hoffman, H, Hotez, PJ, Hoy, D, Huang, JJ, Ibeanusi, SE, Jacobsen, KH, James, SL, Jarvis, D, Jasrasaria, R, Jayaraman, S, Johns, N, Jonas, JB, Karthikeyan, G, Kassebaum, N, Kawakami, N, Keren, A, Khoo, JP, King, CH, Knowlton, LM, Kobusingye, O, Koranteng, A, Krishnamurthi, R, Lalloo, R, Laslett, LL, Lathlean, T, Leasher, JL, Lee, YY, Leigh, J, Lim, SS, Limb, E, Lin, JK, Lipnick, M, Lipshultz, SE, Liu, W, Loane, M, Ohno, SL, Lyons, R, Ma, J, Mabweijano, J, MacIntyre, MF, Malekzadeh, R, Mallinger, L, Manivannan, S, Marcenes, W, March, L, Margolis, DJ, Marks, GB, Marks, R, Matsumori, A, Matzopoulos, R, Mayosi, BM, McAnulty, JH, McDermott, MM, McGill, N, McGrath, J, Medina-Mora, ME, Meltzer, M, Mensah, GA, Merriman, TR, Meyer, AC, Miglioli, V, Miller, M, Miller, TR, Mitchell, PB, Mocumbi, AO, Moffitt, TE, Mokdad, AA, Monasta, L, Montico, M, Moradi-Lakeh, M, Moran, A, Morawska, L, Mori, R, Murdoch, ME, Mwaniki, MK, Naidoo, K, Nair, MN, Naldi, L, Narayan, KM, Nelson, PK, Nelson, RG, Nevitt, MC, Newton, CR, Nolte, S, Norman, P, Norman, R, O’Donnell, M, O’Hanlon, S, Olives, C, Omer, SB, Ortblad, K, Osborne, R, Ozgediz, D, Page, A, Pahari, B, Pandian, JD, Rivero, AP, Patten, SB, Pearce, N, Padilla, RP, Perez-Ruiz, F, Perico, N, Pesudovs, K, Phillips, D, Phillips, MR, Pierce, K, Pion, S, Polanczyk, GV, Polinder, S, Pope, CA 3rd Popova, S, Porrini, E, Pourmalek, F, Prince, M, Pullan, RL, Ramaiah, KD, Ranganathan, D, Razavi, H, Regan, M, Rehm, JT, Rein, DB, Remuzzi, G, Richardson, K, Rivara, FP, Roberts, T, Robinson, C, De Leòn, FR, Ronfani, L, Room, R, Rosenfeld, LC, Rushton, L, Sacco, RL, Saha, S, Sampson, U, Sanchez-Riera, L, Sanman, E, Schwebel, DC, Scott, JG, Segui-Gomez, M, Shahraz, S, Shepard, DS, Shin, H, Shivakoti, R, Singh, D, Singh, GM, Singh, JA, Singleton, J, Sleet, DA, Sliwa, K, Smith, E, Smith, JL, Stapelberg, NJ, Steer, A, Steiner, T, Stolk, WA, Stovner, LJ, Sudfeld, C, Syed, S, Tamburlini, G, Tavakkoli, M, Taylor, HR, Taylor, JA, Taylor, WJ, Thomas, B, Thomson, WM, Thurston, GD, Tleyjeh, IM, Tonelli, M, Towbin, JA, Truelsen, T, Tsilimbaris, MK, Ubeda, C, Undurraga, EA, van der Werf, MJ, van Os, J, Vavilala, MS, Venketasubramanian, N, Wang, M, Wang, W, Watt, K, Weatherall, DJ, Weinstock, MA, Weintraub, R, Weisskopf, MG, Weissman, MM, White, RA, Whiteford, H, Wiersma, ST, Wilkinson, JD, Williams, HC, Williams, SR, Witt, E, Wolfe, F, Woolf, AD, Wulf, S, Yeh, PH, Zaidi, AK, Zheng, ZJ, Zonies, D, Lopez, AD, Murray, CJ, AlMazroa, MA and Memish, ZA (2012) Years lived with disability (YLDs) for 1160 sequelae of 289 diseases and injuries 1990–2010: a systematic analysis for the Global Burden of Disease Study 2010. Lancet 380, 2163–2196.CrossRefGoogle ScholarPubMed
Waddell, G (1987) Volvo award in clinical sciences. A new clinical model for the treatment of low-back pain. Spine (Phila Pa 1976) 12, 632644.CrossRefGoogle ScholarPubMed
Waddell, G and Burton, AK (2005) Concepts of rehabilitation for the management of low back pain. Best Practice & Research: Clinical Rheumatology 19, 655670.CrossRefGoogle ScholarPubMed
WHO. International Classification of Diseases and Related Health Problems (ICD) 10 system https://icd.who.int/browse10/2010/en#/XIII [Online]. World Health Organisation.Google Scholar
Williams, RM, Westmorland, MG, Lin, CA, Schmuck, G and Creen, M (2007) Effectiveness of workplace rehabilitation interventions in the treatment of work-related low back pain: a systematic review. Disability and Rehabilitation 29, 607624.CrossRefGoogle ScholarPubMed
Yang, S, Kim, W, Choi, KH and Yi, YG (2016) Influence of occupation on lumbar spine degeneration in men: the Korean National Health and Nutrition Examination Survey 2010–2013. International Archives of Occupational and Environmental Health 89, 13211328.CrossRefGoogle ScholarPubMed
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Figure 1. Flow chart of selection of the cohorts during 2010–2011, in age 20–60 years with MSP diagnoses1Multimodal rehabilitation cohort.2Reference cohort.3MMR group inclusion criteria: in a register 20100101-20111231, age 20–60 years, diagnostic code according to the National Rehabilitation Program, no withdrawal, residence in Region Skåne, or deceased through 2013, no reused personal code number. At least six treatment sessions within MMR treatment period. Minimum 6 and maximum 26 weeks as MMR treatment period. At least six treatment sessions over a period of maximum six weeks. Over this six-week period at least one treatment session during four weeks in the six-week period. Either no visit or at most one visit to the rehabilitation medicine centre with a registered pain diagnosis (in accordance with the National Rehabilitation Program) over the years 2008–2012.4Reference group inclusion criteria: age 20–60 years, in Region Skåne medical record with no withdrawal, any registered diagnostic code within the definition from the National Rehabilitation Program as main diagnose within Hälsovalet during 20100101-20111231, code registered at any office visit, within defined care area (primary care, psychiatric or somatic care), outpatient care, diagnose registered by physician, physiotherapist, psychologist or team, residency in Region Skåne or deceased, no reused personal code number. Either no visit or at most one visit to the rehabilitation medicine centre with a registered pain diagnosis (in accordance with the National Rehabilitation Program) over the years 2008–2012. After inclusion, at least one or more office visits within three months (92 days) that fulfil the same criteria regarding type and setting for MMR diagnose.

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Table 1. Baseline characteristics of participants in the MMR group and in the reference group

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Table 2. Sick leave (≥15 days net) and employment status over time for the MMR group and for the reference group

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Figure 2. Number of sick leave days (over three months/a quarter), before and after baseline, in the MMR group and the reference group