Exercise therapy for treatment of acute non-specific low back pain

Wilhelmina IJzelenberg; Teddy Oosterhuis; Jill A Hayden; Bart W Koes; Maurits W van Tulder; Sidney M Rubinstein; Annemarie de Zoete

doi:10.1002/14651858.CD009365.pub2

Exercise therapy for treatment of acute non-specific low back pain

Wilhelmina IJzelenberg^*
, Teddy Oosterhuis
, Jill A Hayden
, Bart W Koes
, Maurits W van Tulder
, Sidney M Rubinstein
, Annemarie de Zoete

^*Corresponding author for this work

General Practice

Research output: Contribution to journal › Review article › Academic › peer-review

22 Citations (Scopus)

Abstract

BACKGROUND:

Low back pain (LBP) is the leading cause of disability globally. It generates considerable direct costs (healthcare) and indirect costs (lost productivity). The many available treatments for LBP include exercise therapy, which is practised extensively worldwide.

OBJECTIVES:

To evaluate the benefits and harms of exercise therapy for acute non-specific low back pain in adults compared to sham/placebo treatment or no treatment at short-term, intermediate-term, and long-term follow-up.

SEARCH METHODS:

This is an update of a Cochrane Review first published in 2005. We conducted an updated search for randomised controlled trials (RCTs) in CENTRAL, MEDLINE, Embase, four other databases, and two trial registers. We screened the reference lists of all included studies and relevant systematic reviews published since 2004.

SELECTION CRITERIA:

We included RCTs that examined the effects of exercise therapy on non-specific LBP lasting six weeks or less in adults. Major outcomes for this review were pain, functional status, and perceived recovery. Minor outcomes were return to work, health-related quality of life, and adverse events. Our main comparisons were exercise therapy versus sham/placebo treatment and exercise therapy versus no treatment.

DATA COLLECTION AND ANALYSIS:

We used standard Cochrane methods. We evaluated outcomes at short-term follow-up (time point within three months and closest to six weeks after randomisation; main follow-up), intermediate-term follow-up (between nine months and closest to six months), and long-term follow-up (after nine months and closest to 12 months); and we used GRADE to assess the certainty of the evidence for each outcome.

MAIN RESULTS:

We included 23 studies (13 from the previous review, 10 new studies) that involved 2674 participants and provided data for 2637 participants. Three small studies are awaiting classification, and four eligible studies are ongoing. Included studies were conducted in Europe (N = 9), the Asia-Pacific region (N = 9), and North America (N = 5); and most took place in a primary care setting (N = 12), secondary care setting (N = 6), or both (N = 1). In most studies, the population was middle-aged and included men and women. We judged 10 studies (43%) at low risk of bias with regard to sequence generation and allocation concealment. Blinding is not feasible in exercise therapy, introducing performance and detection bias. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on pain scores in the short term (mean difference (MD) -0.80, 95% confidence interval (CI) -5.79 to 4.19; 1 study, 299 participants). The absolute difference was 1% less pain (95% CI 4% more to 6% less), and the relative difference was 4% less pain (95% CI 20% more to 28% less). The mean pain score was 20.1 (standard deviation (SD) 21) for the intervention group and 20.9 (SD 23) for the control group. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on functional status scores in the short term (MD 2.00, 95% CI -2.20 to 6.20; 1 study, 299 participants). The absolute difference was 2% worse functional status (95% CI 2% better to 6% worse), and the relative difference was 15% worse (95% CI 17% better to 47% worse). The mean functional status score was 15.3 (SD 19) for the intervention group and 13.3 (SD 18) for the control group. We downgraded the certainty of the evidence for pain and functional status by one level for risk of bias and by two levels for imprecision (only one study with fewer than 400 participants). There is very low-certainty evidence that exercise therapy compared with no treatment has no clinically relevant effect on pain or functional status in the short term (2 studies, 157 participants). We downgraded the certainty of the evidence by two levels for imprecision and by one level for inconsistency. One study associated exercise with small benefits and the other found no differences. The first study was conducted in an occupational healthcare centre, where participants received one exercise therapy session. The other study was conducted in secondary and tertiary care settings, where participants received treatment three times per week for six weeks. We did not pool data from these studies owing to considerable clinical heterogeneity. In two studies, there were no reported adverse events. One study reported adverse events unrelated to exercise therapy. The remaining studies did not report whether any adverse events had occurred. Owing to insufficient reporting of adverse events, we were unable to reach any conclusions on the safety or harms related to exercise therapy.

AUTHORS' CONCLUSIONS:

Exercise therapy compared to sham/placebo treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. Exercise therapy compared to no treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. We downgraded the certainty of the evidence to very low for inconsistency, risk of bias concerns, and imprecision (few participants).

Original language	English
Article number	CD009365
Pages (from-to)	CD009365
Journal	The Cochrane database of systematic reviews
Volume	2023
Issue number	8
DOIs	https://doi.org/10.1002/14651858.CD009365.pub2
Publication status	Published - 30 Aug 2023

Bibliographical note

Funding Information:
Eleven studies did not report funding sources. The remaining studies were funded by a government body (Cherkin 1998; Faas 1993; Gilbert 1985), a non-profit organisation (Brennan 2006; Chok 1999; Farrell 1982; Grunnesjö 2011; Hides 1996; Sokunbi 2014; Underwood 1998; Waterworth 1985), or both (Machado 2010). We thank Shireen Harbin and Maggie Tiong for their assistance with the development and execution of the search strategies. We also thank Dr Antti Malmivaara for his work in the original review, which laid the groundwork for this update. We acknowledge the peer reviewers Prof Stefano Negrini "La Statale", Milan – IRCCS Istituto Ortopedico Galeazzi, Milan, Italy; Prof Roger Chou, Department of Medical Informatics and Clinical Epidemiology, Oregon Health & Science University, Portland, USA; and copy-editor Julia Turner, Cochrane Central Production Service.

Funding Information:
Funding: study initiated by Dutch College of General Practitioners and financially supported by the Preventie Fonds (governmental)

Funding Information:
Funding source: funded by AMF-Sjukforsakring, Stockholm, Sweden (non-profit)

Funding Information:
Funding: funded by the John P. Kelly Mater Research Foundation, Mater Hospitals, Brisbane, The Physiotherapy Research Foundation, Australia, The Wenkart Foundation, Australia, and the Manipulative Physiotherapists Association of Queensland, Queensland, Australia (non-profit)

Funding Information:
Funding: funded by Agency for Health Care Policy and Research (Governmental)

Funding Information:
Funding: funded by Hawkes Bay Medical Research Foundation (non-profit)

Funding Information:
Funding: funded by the National Social Insurance Board, Stockholm County Council, Stockholm Clinic – Stay Active, Stockholm and Uppsala University (non-profit) Declaration of interest: the authors declare that they have no conflicts of interest regarding this manuscript.

Funding Information:
Funding: funded by Physiotherapy Department, Singapore General Hospital (non-profit)

Funding Information:
Funding: funded by Deseret Foundation (non-profit)

Funding Information:
Funding: funded by the Royal College of General Practitioners (non-profit)

Funding Information:
Funding: funded by the University of Sydney, Australia. Personal grants from Fundação de Amparo à Pesquisa do Estado de Minas Gerais (FAPEMIG), Brazil, the Australian Government and the National Health & Medical Research Council (NHMRC), Australia. (Non-profit/governmental).

Funding Information:
Funding: funded by Ontario Ministry of Health (DM 500; Governmental)

Publisher Copyright:
Copyright © 2023 The Cochrane Collaboration. Published by John Wiley & Sons, Ltd.

Access to Document

10.1002/14651858.CD009365.pub2

Cite this

@article{82a5200e637244cb90f89a4442ed906b,

title = "Exercise therapy for treatment of acute non-specific low back pain",

abstract = "BACKGROUND: Low back pain (LBP) is the leading cause of disability globally. It generates considerable direct costs (healthcare) and indirect costs (lost productivity). The many available treatments for LBP include exercise therapy, which is practised extensively worldwide.OBJECTIVES: To evaluate the benefits and harms of exercise therapy for acute non-specific low back pain in adults compared to sham/placebo treatment or no treatment at short-term, intermediate-term, and long-term follow-up.SEARCH METHODS: This is an update of a Cochrane Review first published in 2005. We conducted an updated search for randomised controlled trials (RCTs) in CENTRAL, MEDLINE, Embase, four other databases, and two trial registers. We screened the reference lists of all included studies and relevant systematic reviews published since 2004.SELECTION CRITERIA:We included RCTs that examined the effects of exercise therapy on non-specific LBP lasting six weeks or less in adults. Major outcomes for this review were pain, functional status, and perceived recovery. Minor outcomes were return to work, health-related quality of life, and adverse events. Our main comparisons were exercise therapy versus sham/placebo treatment and exercise therapy versus no treatment.DATA COLLECTION AND ANALYSIS:We used standard Cochrane methods. We evaluated outcomes at short-term follow-up (time point within three months and closest to six weeks after randomisation; main follow-up), intermediate-term follow-up (between nine months and closest to six months), and long-term follow-up (after nine months and closest to 12 months); and we used GRADE to assess the certainty of the evidence for each outcome.MAIN RESULTS:We included 23 studies (13 from the previous review, 10 new studies) that involved 2674 participants and provided data for 2637 participants. Three small studies are awaiting classification, and four eligible studies are ongoing. Included studies were conducted in Europe (N = 9), the Asia-Pacific region (N = 9), and North America (N = 5); and most took place in a primary care setting (N = 12), secondary care setting (N = 6), or both (N = 1). In most studies, the population was middle-aged and included men and women. We judged 10 studies (43\%) at low risk of bias with regard to sequence generation and allocation concealment. Blinding is not feasible in exercise therapy, introducing performance and detection bias. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on pain scores in the short term (mean difference (MD) -0.80, 95\% confidence interval (CI) -5.79 to 4.19; 1 study, 299 participants). The absolute difference was 1\% less pain (95\% CI 4\% more to 6\% less), and the relative difference was 4\% less pain (95\% CI 20\% more to 28\% less). The mean pain score was 20.1 (standard deviation (SD) 21) for the intervention group and 20.9 (SD 23) for the control group. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on functional status scores in the short term (MD 2.00, 95\% CI -2.20 to 6.20; 1 study, 299 participants). The absolute difference was 2\% worse functional status (95\% CI 2\% better to 6\% worse), and the relative difference was 15\% worse (95\% CI 17\% better to 47\% worse). The mean functional status score was 15.3 (SD 19) for the intervention group and 13.3 (SD 18) for the control group. We downgraded the certainty of the evidence for pain and functional status by one level for risk of bias and by two levels for imprecision (only one study with fewer than 400 participants). There is very low-certainty evidence that exercise therapy compared with no treatment has no clinically relevant effect on pain or functional status in the short term (2 studies, 157 participants). We downgraded the certainty of the evidence by two levels for imprecision and by one level for inconsistency. One study associated exercise with small benefits and the other found no differences. The first study was conducted in an occupational healthcare centre, where participants received one exercise therapy session. The other study was conducted in secondary and tertiary care settings, where participants received treatment three times per week for six weeks. We did not pool data from these studies owing to considerable clinical heterogeneity. In two studies, there were no reported adverse events. One study reported adverse events unrelated to exercise therapy. The remaining studies did not report whether any adverse events had occurred. Owing to insufficient reporting of adverse events, we were unable to reach any conclusions on the safety or harms related to exercise therapy.AUTHORS' CONCLUSIONS: Exercise therapy compared to sham/placebo treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. Exercise therapy compared to no treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. We downgraded the certainty of the evidence to very low for inconsistency, risk of bias concerns, and imprecision (few participants).",

author = "Wilhelmina IJzelenberg and Teddy Oosterhuis and Hayden, \{Jill A\} and Koes, \{Bart W\} and \{van Tulder\}, \{Maurits W\} and Rubinstein, \{Sidney M\} and \{de Zoete\}, Annemarie",

note = "Funding Information: Eleven studies did not report funding sources. The remaining studies were funded by a government body (Cherkin 1998; Faas 1993; Gilbert 1985), a non-profit organisation (Brennan 2006; Chok 1999; Farrell 1982; Grunnesj{\"o} 2011; Hides 1996; Sokunbi 2014; Underwood 1998; Waterworth 1985), or both (Machado 2010). We thank Shireen Harbin and Maggie Tiong for their assistance with the development and execution of the search strategies. We also thank Dr Antti Malmivaara for his work in the original review, which laid the groundwork for this update. We acknowledge the peer reviewers Prof Stefano Negrini {"}La Statale{"}, Milan – IRCCS Istituto Ortopedico Galeazzi, Milan, Italy; Prof Roger Chou, Department of Medical Informatics and Clinical Epidemiology, Oregon Health \& Science University, Portland, USA; and copy-editor Julia Turner, Cochrane Central Production Service. Funding Information: Funding: study initiated by Dutch College of General Practitioners and financially supported by the Preventie Fonds (governmental) Funding Information: Funding source: funded by AMF-Sjukforsakring, Stockholm, Sweden (non-profit) Funding Information: Funding: funded by the John P. Kelly Mater Research Foundation, Mater Hospitals, Brisbane, The Physiotherapy Research Foundation, Australia, The Wenkart Foundation, Australia, and the Manipulative Physiotherapists Association of Queensland, Queensland, Australia (non-profit) Funding Information: Funding: funded by Agency for Health Care Policy and Research (Governmental) Funding Information: Funding: funded by Hawkes Bay Medical Research Foundation (non-profit) Funding Information: Funding: funded by the National Social Insurance Board, Stockholm County Council, Stockholm Clinic – Stay Active, Stockholm and Uppsala University (non-profit) Declaration of interest: the authors declare that they have no conflicts of interest regarding this manuscript. Funding Information: Funding: funded by Physiotherapy Department, Singapore General Hospital (non-profit) Funding Information: Funding: funded by Deseret Foundation (non-profit) Funding Information: Funding: funded by the Royal College of General Practitioners (non-profit) Funding Information: Funding: funded by the University of Sydney, Australia. Personal grants from Funda{\c c}{\~a}o de Amparo {\`a} Pesquisa do Estado de Minas Gerais (FAPEMIG), Brazil, the Australian Government and the National Health \& Medical Research Council (NHMRC), Australia. (Non-profit/governmental). Funding Information: Funding: funded by Ontario Ministry of Health (DM 500; Governmental) Publisher Copyright: Copyright {\textcopyright} 2023 The Cochrane Collaboration. Published by John Wiley \& Sons, Ltd.",

year = "2023",

month = aug,

day = "30",

doi = "10.1002/14651858.CD009365.pub2",

language = "English",

volume = "2023",

pages = "CD009365",

journal = "The Cochrane database of systematic reviews",

issn = "1361-6137",

publisher = "John Wiley \& Sons Ltd.",

number = "8",

}

TY - JOUR

T1 - Exercise therapy for treatment of acute non-specific low back pain

AU - IJzelenberg, Wilhelmina

AU - Oosterhuis, Teddy

AU - Hayden, Jill A

AU - Koes, Bart W

AU - van Tulder, Maurits W

AU - Rubinstein, Sidney M

AU - de Zoete, Annemarie

N1 - Funding Information: Eleven studies did not report funding sources. The remaining studies were funded by a government body (Cherkin 1998; Faas 1993; Gilbert 1985), a non-profit organisation (Brennan 2006; Chok 1999; Farrell 1982; Grunnesjö 2011; Hides 1996; Sokunbi 2014; Underwood 1998; Waterworth 1985), or both (Machado 2010). We thank Shireen Harbin and Maggie Tiong for their assistance with the development and execution of the search strategies. We also thank Dr Antti Malmivaara for his work in the original review, which laid the groundwork for this update. We acknowledge the peer reviewers Prof Stefano Negrini "La Statale", Milan – IRCCS Istituto Ortopedico Galeazzi, Milan, Italy; Prof Roger Chou, Department of Medical Informatics and Clinical Epidemiology, Oregon Health & Science University, Portland, USA; and copy-editor Julia Turner, Cochrane Central Production Service. Funding Information: Funding: study initiated by Dutch College of General Practitioners and financially supported by the Preventie Fonds (governmental) Funding Information: Funding source: funded by AMF-Sjukforsakring, Stockholm, Sweden (non-profit) Funding Information: Funding: funded by the John P. Kelly Mater Research Foundation, Mater Hospitals, Brisbane, The Physiotherapy Research Foundation, Australia, The Wenkart Foundation, Australia, and the Manipulative Physiotherapists Association of Queensland, Queensland, Australia (non-profit) Funding Information: Funding: funded by Agency for Health Care Policy and Research (Governmental) Funding Information: Funding: funded by Hawkes Bay Medical Research Foundation (non-profit) Funding Information: Funding: funded by the National Social Insurance Board, Stockholm County Council, Stockholm Clinic – Stay Active, Stockholm and Uppsala University (non-profit) Declaration of interest: the authors declare that they have no conflicts of interest regarding this manuscript. Funding Information: Funding: funded by Physiotherapy Department, Singapore General Hospital (non-profit) Funding Information: Funding: funded by Deseret Foundation (non-profit) Funding Information: Funding: funded by the Royal College of General Practitioners (non-profit) Funding Information: Funding: funded by the University of Sydney, Australia. Personal grants from Fundação de Amparo à Pesquisa do Estado de Minas Gerais (FAPEMIG), Brazil, the Australian Government and the National Health & Medical Research Council (NHMRC), Australia. (Non-profit/governmental). Funding Information: Funding: funded by Ontario Ministry of Health (DM 500; Governmental) Publisher Copyright: Copyright © 2023 The Cochrane Collaboration. Published by John Wiley & Sons, Ltd.

PY - 2023/8/30

Y1 - 2023/8/30

N2 - BACKGROUND: Low back pain (LBP) is the leading cause of disability globally. It generates considerable direct costs (healthcare) and indirect costs (lost productivity). The many available treatments for LBP include exercise therapy, which is practised extensively worldwide.OBJECTIVES: To evaluate the benefits and harms of exercise therapy for acute non-specific low back pain in adults compared to sham/placebo treatment or no treatment at short-term, intermediate-term, and long-term follow-up.SEARCH METHODS: This is an update of a Cochrane Review first published in 2005. We conducted an updated search for randomised controlled trials (RCTs) in CENTRAL, MEDLINE, Embase, four other databases, and two trial registers. We screened the reference lists of all included studies and relevant systematic reviews published since 2004.SELECTION CRITERIA:We included RCTs that examined the effects of exercise therapy on non-specific LBP lasting six weeks or less in adults. Major outcomes for this review were pain, functional status, and perceived recovery. Minor outcomes were return to work, health-related quality of life, and adverse events. Our main comparisons were exercise therapy versus sham/placebo treatment and exercise therapy versus no treatment.DATA COLLECTION AND ANALYSIS:We used standard Cochrane methods. We evaluated outcomes at short-term follow-up (time point within three months and closest to six weeks after randomisation; main follow-up), intermediate-term follow-up (between nine months and closest to six months), and long-term follow-up (after nine months and closest to 12 months); and we used GRADE to assess the certainty of the evidence for each outcome.MAIN RESULTS:We included 23 studies (13 from the previous review, 10 new studies) that involved 2674 participants and provided data for 2637 participants. Three small studies are awaiting classification, and four eligible studies are ongoing. Included studies were conducted in Europe (N = 9), the Asia-Pacific region (N = 9), and North America (N = 5); and most took place in a primary care setting (N = 12), secondary care setting (N = 6), or both (N = 1). In most studies, the population was middle-aged and included men and women. We judged 10 studies (43%) at low risk of bias with regard to sequence generation and allocation concealment. Blinding is not feasible in exercise therapy, introducing performance and detection bias. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on pain scores in the short term (mean difference (MD) -0.80, 95% confidence interval (CI) -5.79 to 4.19; 1 study, 299 participants). The absolute difference was 1% less pain (95% CI 4% more to 6% less), and the relative difference was 4% less pain (95% CI 20% more to 28% less). The mean pain score was 20.1 (standard deviation (SD) 21) for the intervention group and 20.9 (SD 23) for the control group. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on functional status scores in the short term (MD 2.00, 95% CI -2.20 to 6.20; 1 study, 299 participants). The absolute difference was 2% worse functional status (95% CI 2% better to 6% worse), and the relative difference was 15% worse (95% CI 17% better to 47% worse). The mean functional status score was 15.3 (SD 19) for the intervention group and 13.3 (SD 18) for the control group. We downgraded the certainty of the evidence for pain and functional status by one level for risk of bias and by two levels for imprecision (only one study with fewer than 400 participants). There is very low-certainty evidence that exercise therapy compared with no treatment has no clinically relevant effect on pain or functional status in the short term (2 studies, 157 participants). We downgraded the certainty of the evidence by two levels for imprecision and by one level for inconsistency. One study associated exercise with small benefits and the other found no differences. The first study was conducted in an occupational healthcare centre, where participants received one exercise therapy session. The other study was conducted in secondary and tertiary care settings, where participants received treatment three times per week for six weeks. We did not pool data from these studies owing to considerable clinical heterogeneity. In two studies, there were no reported adverse events. One study reported adverse events unrelated to exercise therapy. The remaining studies did not report whether any adverse events had occurred. Owing to insufficient reporting of adverse events, we were unable to reach any conclusions on the safety or harms related to exercise therapy.AUTHORS' CONCLUSIONS: Exercise therapy compared to sham/placebo treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. Exercise therapy compared to no treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. We downgraded the certainty of the evidence to very low for inconsistency, risk of bias concerns, and imprecision (few participants).

AB - BACKGROUND: Low back pain (LBP) is the leading cause of disability globally. It generates considerable direct costs (healthcare) and indirect costs (lost productivity). The many available treatments for LBP include exercise therapy, which is practised extensively worldwide.OBJECTIVES: To evaluate the benefits and harms of exercise therapy for acute non-specific low back pain in adults compared to sham/placebo treatment or no treatment at short-term, intermediate-term, and long-term follow-up.SEARCH METHODS: This is an update of a Cochrane Review first published in 2005. We conducted an updated search for randomised controlled trials (RCTs) in CENTRAL, MEDLINE, Embase, four other databases, and two trial registers. We screened the reference lists of all included studies and relevant systematic reviews published since 2004.SELECTION CRITERIA:We included RCTs that examined the effects of exercise therapy on non-specific LBP lasting six weeks or less in adults. Major outcomes for this review were pain, functional status, and perceived recovery. Minor outcomes were return to work, health-related quality of life, and adverse events. Our main comparisons were exercise therapy versus sham/placebo treatment and exercise therapy versus no treatment.DATA COLLECTION AND ANALYSIS:We used standard Cochrane methods. We evaluated outcomes at short-term follow-up (time point within three months and closest to six weeks after randomisation; main follow-up), intermediate-term follow-up (between nine months and closest to six months), and long-term follow-up (after nine months and closest to 12 months); and we used GRADE to assess the certainty of the evidence for each outcome.MAIN RESULTS:We included 23 studies (13 from the previous review, 10 new studies) that involved 2674 participants and provided data for 2637 participants. Three small studies are awaiting classification, and four eligible studies are ongoing. Included studies were conducted in Europe (N = 9), the Asia-Pacific region (N = 9), and North America (N = 5); and most took place in a primary care setting (N = 12), secondary care setting (N = 6), or both (N = 1). In most studies, the population was middle-aged and included men and women. We judged 10 studies (43%) at low risk of bias with regard to sequence generation and allocation concealment. Blinding is not feasible in exercise therapy, introducing performance and detection bias. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on pain scores in the short term (mean difference (MD) -0.80, 95% confidence interval (CI) -5.79 to 4.19; 1 study, 299 participants). The absolute difference was 1% less pain (95% CI 4% more to 6% less), and the relative difference was 4% less pain (95% CI 20% more to 28% less). The mean pain score was 20.1 (standard deviation (SD) 21) for the intervention group and 20.9 (SD 23) for the control group. There is very low-certainty evidence that exercise therapy compared with sham/placebo treatment has no clinically relevant effect on functional status scores in the short term (MD 2.00, 95% CI -2.20 to 6.20; 1 study, 299 participants). The absolute difference was 2% worse functional status (95% CI 2% better to 6% worse), and the relative difference was 15% worse (95% CI 17% better to 47% worse). The mean functional status score was 15.3 (SD 19) for the intervention group and 13.3 (SD 18) for the control group. We downgraded the certainty of the evidence for pain and functional status by one level for risk of bias and by two levels for imprecision (only one study with fewer than 400 participants). There is very low-certainty evidence that exercise therapy compared with no treatment has no clinically relevant effect on pain or functional status in the short term (2 studies, 157 participants). We downgraded the certainty of the evidence by two levels for imprecision and by one level for inconsistency. One study associated exercise with small benefits and the other found no differences. The first study was conducted in an occupational healthcare centre, where participants received one exercise therapy session. The other study was conducted in secondary and tertiary care settings, where participants received treatment three times per week for six weeks. We did not pool data from these studies owing to considerable clinical heterogeneity. In two studies, there were no reported adverse events. One study reported adverse events unrelated to exercise therapy. The remaining studies did not report whether any adverse events had occurred. Owing to insufficient reporting of adverse events, we were unable to reach any conclusions on the safety or harms related to exercise therapy.AUTHORS' CONCLUSIONS: Exercise therapy compared to sham/placebo treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. Exercise therapy compared to no treatment may have no clinically relevant effect on pain or functional status in the short term in people with acute non-specific LBP, but the evidence is very uncertain. We downgraded the certainty of the evidence to very low for inconsistency, risk of bias concerns, and imprecision (few participants).

UR - https://www.scopus.com/pages/publications/85009402996

U2 - 10.1002/14651858.CD009365.pub2

DO - 10.1002/14651858.CD009365.pub2

M3 - Review article

C2 - 37646368

SN - 1361-6137

VL - 2023

SP - CD009365

JO - The Cochrane database of systematic reviews

JF - The Cochrane database of systematic reviews

IS - 8

M1 - CD009365

ER -

Exercise therapy for treatment of acute non-specific low back pain

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