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Graded exercise therapy
Graded exercise therapy
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Graded exercise therapy
Other namesGET
SpecialtyPhysical therapy

Graded exercise therapy (GET) is a programme of physical activity that starts very slowly and gradually increases over time, intended as a treatment for myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS). Most public health bodies, including the CDC and NICE, consider it ineffective, and its safety is disputed.[1][2][3] However, GET still enjoys support from a minority of clinicians and organizations.

Description

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A graded exercise programme starts with a physiotherapist or exercise physiologist assessing the patient's current abilities and negotiating goals. The patient then begins exercising at a level within their capabilities. The patient and therapist increase the duration of sessions, typically by 10-20% every 1-2 weeks, until they can perform 30 minutes of light exercise five times a week. Then the intensity is raised if desired.[4][5][6]

The exercise can be any activity that can be titrated, such as walking, jogging, swimming, using exercise machines, and these may be mixed to add variety. Increasing the intensity can be more challenging than increasing duration, and a heart rate monitor may be employed to track intensity. If exercise exacerbates a patient's symptoms, they may be encouraged to pause the increases until symptoms become manageable again.[4][5] In other cases, the patient is expected to continue fixed increases in activity regardless of the degree of post-exertional malaise they experience.[7]

Patients are told that if exercise provokes symptoms, it is a typical response to becoming more active rather than a pathological process that causes permanent damage. Adverse effects may be increased if the practitioner is unfamiliar with CFS or exercise is not ramped up appropriately.[4]

Model

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A chart that shows fatigue and other symptoms, cognitions, emotional distress, anxiety and depression, frustration, rest, and symptom focusing as factors perpetuating ME/CFS
The discredited cognitive-behvioral model that underlies graded exercise

GET is based on the discredited model that people with ME/CFS avoid exerting themselves due to fear of triggering symptoms such as pain and fatigue, which causes deconditioning and further worsening of symptoms.[2][8] Excessive focus on symptoms and attributing illness to biological factors are also said perpetuate the illness.[8][5]

This model lacks evidence, contradicts patient experience, and fails to account for the biological evidence that ME/CFS is a serious medical condition.[8][9][10] Further, mental health problems or deconditioning do not cause ME/CFS.[11][12][13]

Effectiveness

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Graded exercise therapy is generally considered to be an ineffective, outdated standard of care that can worsen the condition.[2] GET does not enable patients to increase their activity levels (as objectively measured by actigraphy)[14] or return to work.[15]

Major public health bodies recommend against GET. The CDC stopped recommending GET in 2017,[16] and says that people with ME/CFS do not tolerate vigorous exercise. NICE's 2021 guidance for ME/CFS removed graded exercise, which was recommended in the previous 2007 version,[17] and cautions against "any programme that...uses fixed incremental increases in physical activity or exercise, for example, graded exercise therapy."[18][7] According to NICE, studies of GET have been of poor or very poor quality.

Two regional departments of health, in New York state and Victoria, Australia, say GET is ineffective and potentially dangerous.[12][11] The Mayo Clinic consensus recommendations for the treatment of ME/CFS also oppose GET.[2]

ME/CFS patient organizations strongly oppose GET because they disagree that mental health problems are a cause of their illness and because many patients anecdotally report harms due to GET.[8]

As of 2015, the Royal Australian College of General Practitioners still supported graded exercise for CFS.[4]

Research

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Outcomes reported by the PACE trial

The available research into GET is of poor or very poor quality.[7][2] These studies generally have limited tracking of adverse effects,[3][2] employ outdated definitions of ME/CFS that do not require post-exertional malaise,[3] and rely on subjective self-reported outcome measures within unblinded trials, making them prone to placebo effects.[15]

The largest study on GET, the 2011 PACE trial, reported that GET and cognitive-behavioral therapy were safe and resulted in recovery for 22% of participants and improvement for 60%. There has since been considerable debate over the validity of the results. Outcome measures were modified mid-trial without a clear rationale.[19] When the data were reanalyzed utilising the original protocol, the rate of improvement was only 21%, and recovery was just 4%.[19] While trial participants reported subjective improvement, there was no clinically significant improvement in fitness according to the 6-minute walk test, an objective outcome.[15]

A 2022 review commissioned by the CDC concluded that weak evidence suggests that GET has "small to moderate" benefits, including reduced fatigue, decreased depression and anxiety, and better sleep. It said these results are of uncertain relevance to people with severe ME/CFS, a diagnosis according to modern criteria, or post-exertional malaise. According to the review, limited evidence suggests that GET is not harmful, but that reporting of harms was "suboptimal."[20]

A 2019 Cochrane review of 8 studies concluded that GET "probably" reduces fatigue but that evidence on long-term effectiveness and potential harms are very limited. The studies analyzed employed older definitions of CFS, so the effects on current patient cohorts may be different.[6] An independent analysis of the same studies reached the opposite conclusion based on the unreliability of subjective outcomes in unblinded trials, lack of objective improvements in physical fitness and employment, and insufficient tracking of adverse events.[15]

The ME Association asserts that GET causes a significant fraction of patients to get worse: 30% to 50% in self-reported patient questionnaires.[21] According to the Mayo Clinic Proceedings recommendations, 54% to 74% reported harm.[2]

Graded exercise therapy has also been trialled in long COVID; a retrospective study showed adherence predicted outcomes, implying some utility of GET in this patient group.[22]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Graded exercise therapy

View on Grokipedia
from Grokipedia
Graded exercise therapy (GET) is a structured behavioral intervention for (ME/CFS) that involves progressively increasing physical activity levels, often via predetermined quotas, to purportedly reverse perceived deconditioning and improve function. Originating in the within a framework emphasizing psychological and behavioral factors in perpetuating fatigue, GET was endorsed by the UK's National Institute for Health and Care Excellence (NICE) in 2007 as a treatment for mild to moderate cases, based on early s reporting subjective symptom relief. The 2011 PACE , a large randomized controlled study, claimed GET led to meaningful reductions in fatigue and improvements in physical function compared to adaptive pacing or standard care, influencing international guidelines. However, methodological critiques emerged, including the PACE trial's post-hoc changes to outcome measures and reliance on subjective self-reports without corresponding objective gains, such as in actigraphy-measured activity or employment status. Reanalyses using the trial's original protocol criteria showed recovery rates from GET as low as 4.4%, not statistically superior to controls. Evidence of harm, particularly in patients experiencing (PEM)—a hallmark of ME/CFS involving metabolic and immune disruptions triggered by exertion—prompted reevaluation; fixed exercise escalation can exacerbate PEM, leading to prolonged symptom worsening. In 2021, withdrew its endorsement of GET, citing insufficient evidence of benefit and risks of adverse effects, a shift reflecting patient-reported harms in surveys where up to 55% of recipients described deterioration. Despite some meta-analyses affirming modest effects on self-reported versus no intervention, these are confounded by subjective endpoints and fail to account for objective physiological markers or long-term outcomes, underscoring debates over GET's causal assumptions amid ME/CFS's heterogeneous , potentially including viral persistence and energy impairments. The remains contentious, with proponents viewing it as empowering self-management and critics highlighting iatrogenic potential, especially as biomedical challenges psychosomatic models dominant in earlier advocacy.

History

Origins in Chronic Fatigue Syndrome Treatment

Graded exercise therapy (GET) emerged in the mid-1990s as a targeted intervention for (CFS), primarily developed by clinicians in the who viewed prolonged inactivity as a key perpetuating factor in the condition. Drawing from rehabilitation principles used in cardiac and pulmonary recovery programs, GET adapted gradual increases in to address perceived in CFS patients. Proponents, including physiotherapists collaborating with medical teams, argued that fear-avoidance behaviors led to and cardiovascular inefficiency, forming a vicious cycle of . This approach contrasted with earlier recommendations of strict pacing or , which were seen as reinforcing . The theoretical underpinnings of GET in CFS treatment aligned with the emerging , which posited that while initial triggers might be physiological, ongoing symptoms were maintained by behavioral and cognitive factors such as avoidance of exertion. Early implementations involved individualized programs starting with baseline activity assessment via tools like monitoring, followed by incremental increases in exercise duration and intensity, typically over 12-26 weeks. Sessions emphasized fixed progression schedules rather than symptom-contingent adjustments, with the goal of normalizing activity levels. This protocol was influenced by observations in small case series from the early , where informal graded activity reportedly improved function in select patients without worsening core symptoms long-term. The first specifically evaluating GET for CFS was published in 1997 by Peter D. White and colleagues, involving 60 adults meeting criteria for the syndrome. Participants randomized to GET showed statistically significant reductions in fatigue scores and improvements in physical functioning compared to flexibility training controls, with 70% reporting benefit versus 26% in the control group after 12 weeks. The study, conducted at in , supported claims of efficacy for appropriately prescribed , though it noted limitations such as small sample size and reliance on self-reported outcomes. Subsequent critiques highlighted potential harms from ignoring , but this trial marked a pivotal moment in establishing GET's role in CFS management guidelines.

Key Developments and Influential Studies

Graded exercise therapy (GET) emerged in the early 1990s as a structured intervention for chronic fatigue syndrome (CFS), predicated on the that prolonged inactivity leads to physiological amenable to progressive aerobic training. Early protocols emphasized individualized increments in activity, typically starting from baseline heart rate monitoring and advancing via activities like walking or , with sessions spanning 12-26 weeks. A pivotal early (RCT) was conducted by Fulcher and White in 1997, involving 66 CFS patients assigned to either or flexibility training as a control. The exercise group demonstrated significant reductions in fatigue severity on the Chalder Fatigue Scale (mean decrease from 18.4 to 10.1 points versus 18.7 to 15.1 in controls) and improvements in physical functioning on the scale (from 29 to 63 versus 28 to 36), alongside objective gains in aerobic capacity ( increase of 13%) and muscle strength. These findings, published in , provided initial empirical support for GET's efficacy in reducing symptoms and enhancing function, influencing subsequent adoption in clinical guidelines. The most influential study, the PACE trial, was a large-scale multicenter RCT published in in 2011, randomizing 641 adults meeting criteria for CFS to specialist medical care (SMC) alone or SMC plus adaptive pacing therapy, (CBT), or GET. At 12-month follow-up, GET yielded a mean Chalder Fatigue Questionnaire improvement of -3.2 points relative to SMC and a +7.5-point gain in physical function scores; approximately 31% of GET participants met combined fatigue and function recovery thresholds, compared to 7% in SMC. However, objective measures such as actigraphy-assessed activity levels showed no significant differences across arms, and post-hoc alterations to recovery criteria drew for inflating apparent benefits. Reanalyses using pre-specified thresholds indicated minimal to no recovery rates beyond SMC. Subsequent trials, including the 2017 GETSET study of self-guided GET in 211 , reported modest reductions (Chalder scale improvement of -4.4 points versus no intervention), but patient surveys indicated 51% perceived from prior GET exposure.30577-9/fulltext) A 2019 Cochrane review of eight RCTs (n=1,518) found exercise therapies, including GET, associated with small short-term gains in self-reported physical function and compared to usual care, graded low-quality due to risk of and subjective outcomes. These developments prompted the UK's National Institute for Health and Care Excellence (NICE) to recommend GET in its 2007 CFS guideline but to rescind it in 2021, citing insufficient of benefit and risks of worsening symptoms like post-exertional malaise in myalgic encephalomyelitis/chronic syndrome (ME/CFS). The guideline shift reflected growing recognition that GET may exacerbate symptoms in with metabolic impairments, prioritizing over fixed exercise escalation.

Theoretical Foundations

Biopsychosocial Model Assumptions

The applied to (ME/CFS) assumes that persistent symptoms arise from an interaction of biological, psychological, and social factors, with perpetuation primarily driven by maladaptive behaviors and cognitions rather than unrelenting organic disease. In this framework, initial triggers such as viral infections or stress precipitate , but ongoing results from avoidance of activity due to fear of symptom exacerbation (kinesiophobia), leading to physical and reinforcement of negative illness beliefs. Proponents, including researchers like and Michael Sharpe, posit that these psychological and behavioral elements form a self-sustaining cycle, where "boom-and-bust" activity patterns—alternating overexertion with prolonged rest—further entrench and functional impairment. Graded exercise therapy (GET) derives its rationale from these assumptions, targeting deconditioning through structured, incremental increases in physical activity to normalize function and challenge perceptions of as biologically fixed. The model hypothesizes that patients can achieve recovery by shifting from symptom-focused behaviors to consistent, graded exposure, thereby reversing physiological detraining without invoking primary biomedical barriers to . This approach embeds within cognitive behavioral formulations, where altering attributions of from uncontrollable to manageable responses enables behavioral change. Empirical challenges to these assumptions highlight discrepancies, particularly the prevalence of (PEM) in ME/CFS, a neuroimmune response to that objectively worsens symptoms beyond psychological mediation, as evidenced in patient cohorts and biomarker studies. The model's emphasis on psychological perpetuation has faced scrutiny for potentially minimizing verifiable physiological correlates, such as immune dysregulation and metabolic impairments documented in peer-reviewed investigations, leading bodies like the UK's National Institute for Health and Care Excellence (NICE) in to deem GET inappropriate due to risks of from disregarding PEM. Consequently, while the biopsychosocial framework influenced early GET protocols, its causal attributions remain contested against accumulating data favoring biomedical primacy in symptom maintenance.

Physiological and Deconditioning Hypotheses

The hypothesis underlying graded exercise therapy (GET) for (ME/CFS) proposes that prolonged physical inactivity leads to cardiovascular, , and aerobic impairments, perpetuating symptoms such as and through reduced fitness levels. Proponents, drawing from early observations of lower peak oxygen uptake (VO2 peak) in patient cohorts, argued that these physiological deficits mirror those in sedentary healthy individuals and could be reversed via progressive aerobic training, thereby improving symptom tolerance without addressing an underlying disease process. For instance, a 1998 study of 100 CFS patients reported evidence of physical , including diminished and muscle strength, attributing these to inactivity rather than primary and recommending GET to restore function. Empirical testing via cardiopulmonary exercise testing (CPET) has yielded mixed results on deconditioning's role. Some controlled studies from the early found ME/CFS patients exhibited maximal exercise performance comparable to or worse than deconditioned controls, suggesting inactivity as a key perpetuator, though without isolating it from potential baseline physiological abnormalities. However, subsequent research challenges this as a primary causal mechanism, showing that and reduced in ME/CFS persist even when matched for levels via VO2 peak, indicating independent autonomic or vascular dysfunction. A 2018 Dutch of over 250 patients similarly concluded no association between deconditioning metrics (e.g., fitness levels) and functional impairment, undermining the that inactivity alone drives perpetuation. Recent physiological investigations further refute deconditioning as explanatory, highlighting distinct biomarkers like (PEM) and metabolic shifts not replicable in deconditioned athletes or sedentary controls. For example, 2021-2025 studies using serial CPET demonstrated second-day performance declines in ME/CFS patients—absent in deconditioning—linked to , immune activation, and mitochondrial impairments, suggesting GET's fixed escalation ignores these non-reversible limits. Critics, including analyses in peer-reviewed outlets, note that early supportive evidence often derived from subjective outcomes or small samples influenced by biopsychosocial frameworks, whereas objective metrics reveal deconditioning as correlative at best, not causal, prompting bodies like NICE to deem the hypothesis unsupported in 2021 guidelines. This shift underscores causal realism: symptoms align more with energy production deficits than reversible fitness loss, rendering GET's physiological rationale empirically weak.

Protocol and Implementation

Core Components and Delivery Methods

Graded exercise therapy (GET) involves establishing an individualized baseline of or exercise that a can sustain for five to six days per week, even on poorer symptom days, typically through activities such as short walks or light . This baseline is determined via initial assessment, including activity diaries to track current patterns and avoid "boom-bust" cycles of overexertion followed by prolonged rest. Progression occurs incrementally, with increases in duration of approximately 10-20% per week until reaching 20-30 minutes per session, followed by adjustments in intensity, such as faster pace or added resistance, guided by tools like monitors targeting 60-75% of maximum . Core elements include aerobic exercises (e.g., walking, stationary cycling, or ), supplemented by for flexibility and, in later stages, strengthening exercises like light resistance training, all selected for patient preference and functional relevance. Sessions incorporate warm-ups, cool-downs, and monitoring of perceived exertion using scales like the (6-20), with adjustments if symptoms worsen to stabilize at the current level for 2-4 weeks. Patients maintain daily logs of exercise adherence, symptoms, and setbacks, emphasizing consistency over five days weekly to build endurance without exceeding planned limits. Delivery typically occurs through supervised outpatient sessions led by trained physiotherapists or exercise specialists, structured in phases: initial engagement and planning (sessions 1-3, ~90 minutes), active implementation (sessions 4-12, ~50 minutes weekly), consolidation and discharge preparation (sessions 13-14, fortnightly), and a booster session at 36 weeks. Total sessions range from 12 to 15 over 3-6 months, combining face-to-face reviews of progress, goal negotiation, and homework assignment with self-monitoring devices like pedometers. While primarily clinic-based, elements may extend to or activities, with flexibility for follow-up if needed.

Patient Selection and Monitoring

Patient selection for graded exercise therapy (GET) generally requires a of chronic (CFS) using broad criteria such as the definition, which mandates of definite onset not substantially relieved by rest, accompanied by post-exertional or malaise, and substantial disability in , after exclusion of alternative medical explanations. Participants must typically be adults aged 18 years or older, residing within feasible travel distance to clinics, and demonstrate significant (e.g., scoring 0 or 1 on the binary Chalder Fatigue Scale, indicating severe symptoms) alongside low physical functioning (e.g., physical function subscale score ≤65). Exclusion criteria include primary psychiatric conditions like , organic brain disorders, current , or medical instabilities such as uncontrolled or cardiac issues that contraindicate exercise. Severely affected patients, such as those primarily housebound or bedbound, are often deemed ineligible due to inability to establish baseline activity or attend sessions, limiting GET to those with milder to moderate impairment. Initial assessment for suitability involves screening for comorbidities and establishing baseline tolerance via activity diaries and submaximal tests like the incremental shuttle walk, aiming to identify without provoking excessive symptom worsening. Protocols emphasize selecting patients presumed to benefit from addressing perceived , though this assumes reversibility of symptoms through fixed progression, an assumption challenged by evidence of metabolic dysfunction in ME/CFS subsets. Monitoring entails 10–15 supervised sessions over 12 weeks, supplemented by home-based logging of exercise duration, (if using aerobic modalities), and subjective symptoms via scales like the Chalder Fatigue Questionnaire. Progression follows a structured schedule—increasing activity time by 10–20% weekly if the prior level is tolerated, then shifting to intensity via targets (e.g., 60–80% maximum)—with therapist reviews every 1–2 weeks to verify adherence and adjust prescriptions. Adverse effects are tracked through forms, defining serious harm as hospitalization or marked deterioration (e.g., >50% worsening in scores), prompting dose reduction or referral, but protocols do not mandate pausing for (PEM), a hallmark symptom in ME/CFS that can persist days to weeks. This symptom-blind escalation has been linked to under-detection of harms, as trial data like PACE reported low adverse rates (e.g., 2–3% serious deteriorations across arms) despite patient surveys indicating 20–50% worsening post-GET. Contemporary analyses highlight risks in monitoring, including reliance on self-reported adherence without objective physiological metrics (e.g., repeated CPET to detect anaerobic thresholds), potentially overlooking PEM in patients with neuromuscular intolerance to exertion. Guidelines updated post-2020, such as NICE NG206 (2021), recommend against GET due to insufficient evidence of net benefit and documented harms, advocating instead symptom-contingent pacing with frequent PEM screening via patient diaries or wearables. This shift underscores selection biases in legacy protocols toward non-PEM phenotypes, as broader ME/CFS cohorts show variable exercise responses, with up to 70% reporting sustained detriment from rigid GET.

Evidence of Effectiveness

Short-Term Outcomes from Randomized Trials

Randomized controlled trials (RCTs) of (GET) for chronic fatigue syndrome (CFS) have primarily assessed short-term outcomes through self-reported measures of fatigue and physical function at endpoints of 3-6 months, with mixed results indicating modest benefits over controls in some studies but limited or no superiority in others. The 2011 PACE trial, the largest RCT with 641 participants meeting criteria for CFS, reported at its 6-month primary endpoint that GET, when added to specialist medical care, yielded greater reductions in fatigue scores on the Chalder Fatigue Questionnaire (mean improvement of -7.0 points from baseline versus -2.2 for specialist medical care alone) and improvements in physical functioning on the subscale (mean +7.1 points versus -0.1). These changes met trial thresholds for clinical improvement in 31% of GET participants for fatigue and 35% for physical function, compared to lower rates in control arms, though absolute recovery rates remained low at around 13% using combined criteria. Objective outcomes, such as step count or fitness tests, showed no significant differences between GET and controls. Smaller RCTs have echoed modest subjective gains but highlighted inconsistencies. In the 2017 GETSET trial of 211 patients with CFS, guided GET over 12 weeks increased the odds of clinically important improvement in (Chalder scale) by 77% ( 1.77) and in physical function () by 51% compared to specialist medical care alone, with 40% of GET participants rating themselves much better overall versus 20% in controls.32589-2/fulltext) Similarly, a 2005 RCT of 30 CFS patients found GET reduced symptom focusing and improved self-reported function at 3 months post-treatment, though without a non-exercise control. However, a 2024 RCT comparing GET to activity management in 174 veterans with persistent after found no significant differences in or function at 12 weeks, with both arms showing only small mean improvements (e.g., 2-3 points on scales). Systematic reviews synthesize these findings as supporting moderate short-term reductions in self-reported with GET versus passive controls, based on eight RCTs totaling over 1,000 participants, but with low certainty due to risk of from lack of blinding and reliance on subjective outcomes. One review of 14 RCTs reported 61% of GET recipients achieving significant physical function gains up to 12 months (23 percentage points above controls), and 43% global improvement (26 points above controls), but noted clinical heterogeneity in protocols and exclusion of severe cases, limiting generalizability. No pooled for fatigue was possible across studies due to varying scales, and benefits did not extend to objective physiological measures in trials reporting them.

Long-Term Efficacy and Meta-Analyses

Long-term follow-up data for graded exercise therapy (GET) in (ME/CFS) derive primarily from extensions of randomized controlled trials like PACE, which assessed outcomes at a median of 31 months post-randomization. The official analysis reported sustained improvements in self-reported fatigue (Chalder Fatigue Scale mean difference of -3.6 points vs. usual care) and physical function ( score difference of 6.8 points), but these effects were modest, with no significant group differences emerging beyond the initial 52-week period and absolute recovery rates remaining low at 13% for GET using revised criteria.00317-X/fulltext) Independent reanalyses applying original protocol thresholds for recovery—prospectively specified before trial unblinding—revealed no statistically reliable advantage for GET over control arms, with recovery rates below 10% across groups and no further gains in the extended follow-up. Systematic reviews and meta-analyses have yielded mixed findings on long-term efficacy, often hinging on the inclusion of trials with contested methodologies such as unblinded assessments and post-hoc outcome redefinitions. The Cochrane review, synthesizing eight RCTs (n=1,518) including PACE, concluded moderate-quality evidence for GET reducing fatigue at follow-ups of 50-72 weeks (standardized mean difference -0.66; 95% CI -1.00 to -0.32 vs. usual care or passive therapies), but reported limited data on physical function and no assessment of objective outcomes like or six-minute walk test distances. This review, last updated with studies to , has been critiqued for overlooking adverse events linked to and for embedding flawed trials without sensitivity analyses excluding them, potentially overstating benefits amid evidence of favoring positive psychosocial interventions. More recent evaluations reflect diminished confidence in GET's sustained impact. The UK's National Institute for Health and Care Excellence () guideline update in October 2021, following a comprehensive evidence review, determined that GET demonstrates no clinically important long-term benefits for or function and carries risks of harm, particularly worsening symptoms in patients with PEM; it explicitly advises against its routine offer. A 2025 systematic review and of exercise-based interventions, incorporating post-2014 data, found medium-term (beyond 6 months) functional improvements marginally favoring controls over exercise groups ( -0.15), with high heterogeneity and insufficient power for subgroup analyses on GET specifically. These assessments underscore sparse objective long-term endpoints across studies, with subjective gains prone to expectation bias in non-blinded designs and inconsistent replication in patient-centered outcomes like return to work.

Safety Profile and Adverse Effects

Reported Harms and Incidence Rates

In randomized controlled trials of graded exercise therapy (GET) for (ME/CFS), reported rates of serious adverse events have generally been low. In the PACE trial (n=641 participants, with approximately 160 per arm), the GET arm experienced serious adverse events in 8% of participants (13 cases), with only 1% (2 cases) deemed possibly related to the intervention; non-serious adverse events were common across all arms ( 5 per participant per year) but showed no significant treatment differences (P=0.47). Deteriorations, defined as clinically significant worsening in self-reported physical function (≥8-point drop on scale) or fatigue (≥2-point increase on Chalder scale), occurred in 11% and 7% of GET participants, respectively, with no excess risk compared to adaptive pacing therapy, , or specialist medical care arms. Similar patterns appear in smaller trials, such as a 2018 Cochrane re-analysis, where harms were infrequently and inconsistently reported, often limited to dropouts or transient symptom flares without capturing long-term exacerbations. Patient-reported outcomes from independent surveys contrast sharply with trial data, indicating higher incidence. A synthesis of eight surveys (total n=4,338 ME/CFS patients exposed to GET) found 51% (range 28-82%) reported overall worsening, with 20% (range 7-38%, n=1,808) experiencing substantial deterioration; these included prolonged fatigue increases, reduced mobility, and new symptom onset, often attributed to . Such discrepancies may stem from trial methodologies favoring broad definitions over ME/CFS-specific metrics like sustained symptom escalation, potentially underascertaining harms in self-selected cohorts less representative of severe cases. A 2019 survey of NHS ME/CFS clinics further revealed inconsistent harm monitoring, with many lacking standardized criteria for detecting deterioration. These findings influenced policy, as the UK's National Institute for Health and Care Excellence () 2021 guideline concluded GET shows no net benefit and risks harm—particularly symptom when activity exceeds tolerance—recommending against its routine offer based on trial limitations and patient evidence. International bodies, including the US Agency for Healthcare Research and Quality, have echoed concerns over inadequate harms reporting in GET trials, prioritizing objective measures absent in many studies. Overall incidence remains debated, with trial rates under 10% for serious events but survey data suggesting 50%+ subjective worsening, underscoring needs for improved, ME/CFS-tailored adverse outcome tracking.

Mechanisms of Potential Harm, Including Post-Exertional Malaise

Graded exercise therapy (GET) risks inducing (PEM) in (ME/CFS) by enforcing progressive activity increases that often exceed patients' physiological tolerances, disregarding individualized symptom responses and envelopes. PEM manifests as a delayed (typically 12-72 hours post-exertion) and disproportionate escalation of core symptoms, including profound , musculoskeletal pain, cognitive dysfunction, and , distinguishing it from normal post-exercise recovery. In ME/CFS cohorts, PEM affects over 90% of patients, with as the most intensified symptom, underscoring its centrality to disease . Mechanistically, GET precipitates PEM through impaired mitochondrial , where exertion disrupts function and ATP synthesis rather than enhancing it, leading to accumulated metabolic byproducts like lactate and oxidative damage. Unlike healthy individuals, ME/CFS patients exhibit blunted VO2 peak recovery and persistent anaerobic reliance during repeated exercise bouts, amplifying deficits and delaying restoration. This metabolic intolerance stems from baseline mitochondrial impairments, exacerbated by GET's fixed escalation protocols (e.g., 10-20% weekly increments in trials like PACE), which ignore PEM onset and mandate continuation despite flares. Exertional triggers in GET also activate pathological immune cascades, including heightened innate immunity, surges (e.g., IL-6, IL-8), and , perpetuating a feedback loop of central and symptom amplification. reveals divergent responses to exercise in ME/CFS versus controls, with reduced prefrontal activation and altered neural metabolism indicating non-adaptive adaptations that worsen cognitive and autonomic symptoms during PEM. Repeated PEM episodes from GET may induce cumulative tissue stress, prolonging recovery windows and risking baseline deterioration, as evidenced by objective measures in cardiopulmonary testing showing no fitness gains and heightened post-intervention. These harms arise from GET's foundational assumptions of reversible deconditioning, which overlook PEM's objective biomarkers (e.g., elevated lactate, inflammatory markers), potentially converting transient overexertion into chronic setbacks for vulnerable patients. Re-analyses of randomized trials confirm subjective improvements mask objective stagnation or decline, with PEM-prone subgroups reporting sustained worsening.

Controversies and Criticisms

Methodological Flaws in Pivotal Trials like PACE

The PACE trial, a conducted from 2005 to 2010 and published in in 2011, evaluated graded exercise therapy (GET) alongside other interventions for chronic fatigue syndrome (CFS), reporting improvements primarily based on subjective measures. A key methodological issue was the mid-trial alteration of primary outcome measures after unblinded interim , shifting from objective assessments—such as for physical activity and the six-minute walk test for fitness—to subjective self-reports via the Chalder Fatigue Questionnaire (CFQ) and Short Form-36 physical functioning subscale (SF-36 PF). This change, implemented in 2010 without restarting recruitment or preventing bias, aligned results with expectations under the but undermined the trial's prespecified integrity, as reanalyses using original criteria revealed no significant group differences in fatigue or function at 6 or 12 months. Further flaws included the absence of blinding, rendering the trial open-label and susceptible to performance and detection biases, particularly for subjective endpoints where patient and therapist expectations could influence reporting. Objective data, such as actometer readings, showed no improvement in physical activity levels post-GET, contrasting with self-reported gains and highlighting reliance on measures prone to placebo effects or response biases. Recovery thresholds were also relaxed post-hoc; for instance, the SF-36 PF entry criterion was ≤65, yet "recovery" required only ≥60, allowing baseline overlap and yielding recovery rates of 7-15% for GET under stricter protocol definitions, statistically indistinguishable from controls. High attrition rates—up to 30% non-completion of objective tests in the GET arm—compounded interpretability issues, with analyses employing last-observation-carried-forward imputation that potentially masked deterioration. reporting was inconsistent; while 18% of GET participants experienced serious deterioration in or function, these were not predefined as harms and were downplayed relative to transient worsening in other arms, despite being a core CFS feature exacerbated by fixed exercise escalation in GET protocols. Similar unblinded designs and subjective outcome emphasis appear in other GET trials, such as the 2007 Belgian study, where effect sizes vanished under objective scrutiny. These elements collectively indicate that pivotal trials like PACE overstated GET efficacy through adaptive methodologies that prioritized confirmatory over falsifiable testing.

Discrepancies Between Trial Data and Patient-Reported Outcomes

Clinical trials of (GET) for (ME/CFS), particularly the 2011 PACE trial, reported modest improvements in subjective measures (PROMs) such as fatigue and physical function scales, with effect sizes often below thresholds. Independent reanalyses of PACE data, adhering to the prespecified protocol including binary outcomes and stricter recovery criteria, found no significant benefits for GET over specialist medical care, attributing trial-reported gains to outcome measure changes, bimodal scoring issues, and lack of blinding. Objective measures in PACE, including actigraphy-assessed , similarly showed no GET-related improvements, underscoring potential in unblinded subjective assessments. Patient surveys reveal stark contrasts, with high proportions reporting no benefit or symptom worsening from GET. A Action for ME survey found 50% of GET recipients felt worse, while a 2010 ME Association poll reported 82% experienced no improvement or deterioration, including in many cases. A 2024 patient-reported outcomes study across ME/CFS cohorts yielded a net approval score of -72.2% for GET, with the majority citing harms like exacerbated over benefits. These findings align with NICE's 2021 guideline shift, which prioritized patient evidence of GET harm—evident in surveys showing 55-74% adverse or neutral outcomes—over trial PROMs deemed unreliable due to expectancy effects and non-blinding. Discrepancies persist in long-term data, where PACE follow-ups at 2.5 years showed non-sustained subjective gains without objective correlates, while surveys indicate persistent harm, such as reduced activity tolerance post-GET. Critics attribute trial-patient outcome gaps to researcher allegiance bias in non-blinded designs favoring interventions and underreporting of harms via insensitive PROMs that conflate symptom perception with physiological change. Multiple surveys corroborate that GET often triggers or worsens core ME/CFS features like and PEM, contrasting trial claims of safety and efficacy.

Guidelines and Policy Shifts

Evolution of Recommendations Pre- and Post-2021

Prior to 2021, graded exercise therapy (GET) was recommended by several major health authorities for managing (ME/CFS). The UK's National Institute for Health and Care Excellence () in its 2007 guideline (CG53) advised offering GET, alongside , to individuals with mild or moderate ME/CFS, based on evidence from trials such as the PACE study reporting improvements in fatigue and function. The U.S. Centers for Control and Prevention (CDC) similarly endorsed graded exercise as part of activity strategies in its pre-2021 resources, citing low-to-moderate evidence from systematic reviews associating exercise therapy with modest reductions in fatigue compared to no intervention. In October 2021, published an updated guideline (NG206) following a comprehensive review of over 500 studies, patient surveys, and stakeholder input, which marked a significant departure by explicitly advising against GET. The guideline stated that GET should not be offered, as evidence indicated it provided no reliable long-term benefits and could exacerbate symptoms, particularly (PEM), a cardinal feature of ME/CFS where activity beyond energy limits triggers prolonged worsening. This shift was informed by data showing up to 55% of patients reporting harm from GET in surveys, alongside reanalyses of pivotal trials revealing inflated efficacy when objective measures were prioritized over subjective self-reports. Post-2021, the NICE recommendation influenced policy elsewhere, with organizations like the Scottish Intercollegiate Guidelines Network aligning against fixed-increment exercise programs, emphasizing individualized pacing instead. However, some international bodies, including Australia's Royal Australian College of General Practitioners, retained cautious endorsement of tailored exercise pending further evidence, while the CDC's 2023 systematic review acknowledged low-quality evidence for exercise benefits but highlighted intolerance to vigorous activity in ME/CFS patients without mandating withdrawal. Debates persisted, with critics from institutions like King's College London arguing the NICE evidence review undervalued short-term trial data favoring GET, though NICE defended its conclusions based on methodological rigor and real-world harm reports. By 2023, global patient advocacy groups largely supported the de-emphasis on GET, prioritizing biomedical recognition of ME/CFS over psychosocial interventions.

International Variations and Ongoing Debates

In the , the revised its ME/CFS guidelines in October 2021, explicitly advising against graded exercise therapy (GET) due to a lack of robust evidence for sustained benefits and documented risks of harm, including worsening symptoms from protocols involving fixed increments of exercise regardless of patient-reported fluctuations. This shift contrasted with prior endorsements influenced by trials like PACE, prioritizing instead individualized activity management to avoid (PEM). In the United States, the Centers for Disease Control and Prevention (CDC) discontinued recommendations for GET in 2017, following evidence that patients with ME/CFS often experience symptom exacerbation from , and updated its guidance in May 2024 to emphasize pacing strategies over structured exercise escalation to mitigate PEM relapses. The lacks a unified national guideline as of 2023, with the 2018 Health Council report advocating for expanded biomedical research rather than mandating psychosocial interventions like GET, though some clinical practices persist under older influences; a 2023 patient survey of over 1,500 respondents rated GET as the least effective and most harmful approach compared to alternatives. In , the Royal Australian College of General Practitioners (RACGP) has endorsed incremental akin to GET in resources up to 2023, citing potential reductions in fatigue and , but emerging national guidelines under development in 2024-2025 incorporate cautions from global evidence on PEM risks, reflecting partial alignment with restrictive stances elsewhere. Ongoing debates center on the interpretation of versus real-world experiences, with critics arguing that pivotal studies like PACE overestimated benefits through subjective outcomes and outcome-switching, while surveys consistently report GET-associated harms in 20-50% of cases, including prolonged PEM. Some researchers, including a 2023 from over 50 specialists, challenge NICE's rejection of GET, claiming insufficient of positive meta-analyses showing reductions, though these are contested for relying on low-quality and ignoring subgroup harms in PEM-prone . In 2024, a commentary reinforced against GET recommendations due to PEM , while a December 2024 review asserted probable benefits from exercise versus usual care; however, the latter faced backlash from thousands of and advocates demanding retraction for overlooking adverse event underreporting. By February 2025, canceled a planned update to its 2015 exercise review amid methodological disputes, underscoring unresolved tensions between exercise proponents—often tied to cognitive-behavioral models—and prioritizing causal harm from overexertion in ME/CFS.

Alternatives and Comparative Approaches

Pacing Therapy and Activity Management

Pacing therapy, also referred to as activity pacing or , is a self-management designed for individuals with (ME/CFS) that focuses on balancing daily activities with rest to remain within the patient's limited energy envelope and avoid triggering (PEM). Unlike graded exercise therapy, which incrementally increases activity regardless of symptoms, pacing prioritizes symptom fluctuation awareness, task breakdown into manageable segments, and proactive rest periods to prevent energy crashes. This approach recognizes PEM—a hallmark of ME/CFS involving delayed symptom worsening after minimal exertion—as a physiological barrier rather than a psychological one, aiming to stabilize function over time without risking harm. The core principles of pacing include monitoring personal energy expenditure through tools like tracking or subjective scales, alternating activity with rest in ratios tailored to the individual (e.g., 20-30 minutes of activity followed by equivalent rest), and avoiding "boom-bust" cycles where overactivity leads to prolonged recovery. Implementation often involves on identifying triggers, prioritizing essential tasks, and using adaptive strategies such as pacing breathing or posture during activities. Clinical guidance emphasizes , with no fixed protocols, to accommodate variable symptom severity; for severe cases, this may mean minimal upright time or bed-based adaptations. The UK's National Institute for Health and Care Excellence (NICE) 2021 guidelines endorse pacing as a key non-pharmacological management tool, explicitly advising against therapies that could exacerbate PEM, based on evidence of patient harms from prior approaches. Empirical evidence supports pacing's role in symptom mitigation, though studies are limited by small sample sizes and heterogeneous definitions. A 2023 scoping review of 13 studies involving over 1,000 ME/CFS patients found pacing associated with reduced fatigue severity, improved sleep quality, and enhanced in most cohorts, with no reported worsening of PEM when properly adhered to; qualitative data highlighted perceived benefits in daily functioning. A 2022 and of five randomized controlled trials (n=297) on activity pacing for chronic fatigue syndrome demonstrated moderate effects in lowering fatigue (standardized mean difference -0.48) and psychological distress, alongside small improvements in physical function, outperforming usual care without adverse events linked to overexertion. Activity pacing self-management interventions, tested in a 2015 trial of 72 women with CFS, yielded significant gains in daily activity performance ( 0.72) and reduced activity limitations, sustained at six-month follow-up, via structured goal-setting and energy auditing. Critically, pacing's evidence base derives from patient-centered designs that account for ME/CFS's metabolic and neurological constraints, contrasting with trials of exertion-based therapies often criticized for subjective outcomes and underreporting harms. While some critiques note methodological weaknesses like short durations (typically 6-12 weeks) and reliance on self-report, longitudinal observational data indicate sustained symptom stability, with adherence linked to fewer flares; no high-quality trials report pacing-induced deterioration comparable to PEM risks in exercise protocols. International bodies, including NICE, have shifted toward pacing post-2021, reflecting patient surveys (e.g., over 80% reporting GET harm) and physiological data on energy deficits in ME/CFS. Ongoing research calls for standardized pacing protocols and objective biomarkers to quantify benefits, but current data affirm its safety and utility as a foundational strategy.

Emerging Biomedical Interventions

Rintatolimod, a double-stranded immunomodulator, has shown promise in randomized controlled trials for improving exercise tolerance in ME/CFS patients with disease duration under eight years, with a Phase III trial demonstrating a 39% intra-patient improvement in exercise performance after crossover from (p=0.04). This agent activates Toll-like receptor 3 to enhance activity and production, potentially addressing immune deficits observed in subsets of patients. However, results are limited to smaller cohorts and severe cases, with no FDA approval; it remains experimental in most jurisdictions but is authorized for severe ME/CFS in . Solriamfetol, a dopamine-norepinephrine approved for narcolepsy-related , reduced self-reported daily symptoms in a Phase 4, double-blind, randomized, placebo-controlled trial of adults with ME/CFS over eight weeks of flexible dosing. Participants experienced improvements in severity and related functional domains like and organizing, though the trial's small sample size limits generalizability, and objective measures of tolerance were not assessed. Ongoing explores its role in countering central mechanisms, but long-term safety in ME/CFS remains unestablished. Low-dose naltrexone (LDN, 3-4.5 mg/day), an , has demonstrated symptom relief in retrospective clinical data and case series, with patients reporting reduced , , and improved function via mechanisms including glial cell modulation and restoration of TRPM3 expression in natural killer cells. A Finnish retrospective study of 218 ME/CFS patients found LDN safe and effective for core symptoms, though lacking controls. No large-scale RCTs confirm efficacy, and benefits vary by individual, underscoring the need for prospective trials to validate . Other investigational agents include N-acetylcysteine, targeting in ongoing trials, and lumbrokinase, an enzyme promoting for microclot hypotheses, both in early phases without published outcomes. Antiviral therapies like Paxlovid provide transient symptom relief in post-infectious cases but often lead to relapse, indicating no sustained etiological impact. Overall, these interventions remain preliminary, with calls for larger, mechanism-informed trials to overcome historical replication failures in ME/CFS .

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