To map the existing evidence for candidate treatments for long COVID that were prioritised by clinicians and people with lived experience, and to characterise their feasibility, acceptability and safety.
The study was conducted as a narrative review using pragmatic methods including iterative stakeholder-informed decision-making a monthly-updated evidence search, rapid lay evidence summaries and a structured research prioritisation process.
Potential candidate treatments were identified via a combination of database and trial registry searches. These were then ranked by clinicians and people with lived experience using surveys. Evidence summaries for the top 14 interventions (low-dose naltrexone, antivirals, metformin, nicotine, vagus nerve stimulation, antihistamines, guanfacine, colchicine, nattokinase, intravenous immunoglobulins, monoclonal antibodies, coenzyme Q10, multicomponent rehabilitation packages, and exercise training) were created. Prioritised treatments were collated first by searching a collaborative living evidence database (updated monthly) of relevant systematic reviews and randomised controlled trials and then by conducting supplementary searches of other study designs.
Six of 14 interventions had long-COVID-specific randomised controlled trial (RCT) evidence (exercise [16 RCTs], multicomponent packages [5 RCTs], coenzyme Q10 [2 RCTs], antivirals [1 RCT], vagus nerve stimulation [1 pilot RCT], monoclonal antibodies [1 small RCT]); the remainder relied on indirect or very low-certainty data (e.g., uncontrolled studies or mechanistic rationale). Across interventions, evidence certainty was mostly low to very low, and safety/feasibility varied.
This review prioritises and maps candidate treatments for long COVID. There was insufficient direct evidence to inform clinical recommendations. Rather, the treatments presented in this review represent those that could be rigorously tested in clinical trials as they show biological plausibility and/or are feasible and acceptable to people with lived experience and clinicians.
A review protocol was not prospectively registered because the review adopted an iterative approach to support priority setting rather than clinical guidance.
Long COVID, also known as post-acute sequelae of COVID-19 (PASC), is a significant health concern affecting millions of people globally (
Currently, there are a number of ongoing initiatives that are investigating the efficacy of a wide range of potential long COVID treatments ranging from existing medications for other conditions to novel therapeutic approaches (
Potential interventions to treat long COVID were identified through a multi-component process which is described elsewhere. In brief, it involved systematic literature searches (until January 2025–see
The evidence presented in each summary was collated based on a hierarchical approach. We aimed to first identify relevant SRs and then RCTs from our previous literature searches. If no systematic reviews or RCTs were identified in our library, we conducted a supplementary search to identify evidence from other study designs (e.g., cohort studies, case–control studies). This search was conducted across PubMed, Cochrane Library, Embase and Epistemonikos. We used simple, broad search terms such as the “intervention of interest” AND “long COVID.” This approach was chosen given the heterogeneity of long COVID, the diversity of potential interventions and the very early-stage evidence base.
Studies were selected based on their relevance to the research question and their methodological quality. The selection process was conducted independently by two reviewers, with disagreements resolved through discussion or consultation with a third reviewer. If a systematic review was identified, this was presented as the primary evidence due to their high methodological rigor and ability to establish causal relationships. Any RCTs not included in the systematic review were added in narratively. In the absence of systematic reviews and RCTs, we included non-randomised and observational studies.
The eligibility criteria were as follows:
Population: Adults and adolescents meeting the operational definition of long COVID.
Interventions: Shortlisted candidate treatments.
Comparators: Any (including usual care, sham, no treatment).
Outcomes: Patient-reported and objective measures including fatigue, function, quality of life, cognitive outcomes, post-exertional symptom exacerbation, and safety.
Study designs: Prefer SRs and RCTs; if absent, include non-randomised and observational studies.
Acute COVID treatment studies without long-COVID follow-up, editorials, animal models and in-vitro studies were excluded, but used to explain potential mechanisms of action.
Key information including a brief rationale for the treatment, a summary of the key evidence as well as available safety, feasibility, and acceptability information for the Australian context was summarised into a pre-determined template. The quality of the evidence base was rated to help describe the level of evidence available for each treatment. For example, treatments that had several RCTs underpinning them were rated as high, whereas those that had only case studies were rated as very low. We did not conduct formal risk-of-bias or GRADE assessments, as the purpose of this study was to develop an accessible evidence summary for a general audience. Feasibility included availability in Australia, regulatory status, PBS listing, cost and resource considerations. Acceptability reflected patient and/or clinician willingness, adherence considerations and side-effect and other patient burden (
Fourteen intervention summaries were created based on the prioritisation process.
Summary of 14 long COVID Interventions identified as being most relevant.
| Intervention name | Potential mechanism of action | References | Evidence quality | Summary of Evidence for effectiveness | Safety and feasibility in the Australian context |
|---|---|---|---|---|---|
| Low Dose Naltrexone (LDN) | Reduction of viral replication and persistence | Bonilla et al. ( |
Low | Possible small benefit | Safe and inexpensive |
| 4 non-randomised pre post studies | |||||
| Antivirals | Reduction of viral replication and persistence | Geng et al. ( |
Moderate | No statistically significant improvement in symptoms. | Safe with mild side effects. Can interact with other medicines. Restricted access in Australia |
| 1 RCT | |||||
| Antihistamines | Mast cell and histamine pathway inhibition | Salvucci et al. ( |
Very low | May be effective, but very low quality evidence | Usually safe with minimal side effects. Fairly inexpensive and accessible |
| 1 non-randomised study | |||||
| Nicotine | Receptor-mediated neuromodulation and inflammation reduction | Kloc et al.( |
Very low | Unclear | Rare serious side effects and relatively inexpensive |
| 1 case series | |||||
| Metformin | Mitochondrial, metabolic, inflammatory, and vascular modulation. | ( |
None | Unknown | Safe with minimal side effects and relatively Inexpensive |
| 0 studies | |||||
| Vagus Nerve Stimulation | Autonomic and inflammatory regulation | Khan et al. ( |
Low | Possible small benefit | Safe and relatively inexpensive |
| 1 pilot RCT and 1 non-randomised study | |||||
| Guanfacine | Neuroinflammation reduction and cognitive network support | Arnsten et al. ( |
Very low | Unclear | Fairly safe and relatively inexpensive |
| 1 case series | |||||
| Colchicine | Innate immune and inflammasome suppression; endothelial and anti-fibrotic effects | Reyes et al.( |
None | Unknown | Safe with careful consideration of dosage and relatively inexpensive |
| 0 studies | |||||
| Monoclonal antibodies | Viral clearance and immune modulation | Proal et al. ( |
Low | Probably no benefit | Safe in the short term but limited data on long-term safety. Not accessible for Long COVID in Australia |
| 1 pilot RCT and 1 case series | |||||
| Nattokinase | Microclot and spike protein degradation ( |
Grixti et al. ( |
None | Unknown | Considered safe and relatively inexpensive |
| 0 studies | |||||
| Intravenous immunoglobulin (IVIg) | Immune response | McCarthy et al. ( |
Very low | Unclear | Considered safe but not available as a Long COVID treatment in Australia |
| 1 case series and 2 retrospective case–control studies | |||||
| Coenzyme Q10 | Mitochondrial energy and antioxidant support | Bonakdar and Guarneri ( |
Moderate | Probably no effect | Considered safe and relatively inexpensive |
| 2 RCTs and 1 observational study | |||||
| Multicomponent intervention package (may include symptom management, pacing, sleep regulation and psychological support) | Multisystem functional rehabilitation | Kuut et al. ( |
High | Possible small benefit | Generally safe especially when provided under supervision |
| 5 RCTs | Moderately expensive | ||||
| Exercise training | Cardiopulmonary and functional adaptation | McGregor et al. ( |
High | Possible benefit | Quite safe especially if supervised |
| 16 RCTs | Can be inexpensive |
RCT, Randomised controlled trial; PBS, Pharmaceutical Benefits Scheme.
Low Dose Naltrexone (LDN) may improve long COVID symptoms by acting on underlying inflammatory and pain pathways (
Antivirals (Nirmatrelvir, Molnupiravir, and Remdesivir) may help treat the underlying pathophysiology of long COVID by limiting viral replication, potentially targeting persistent SARS-CoV-2 reservoirs that may cause ongoing long-term symptoms. The best available evidence comes from a moderate-quality RCT of 155 participants which found no significant improvement between patients treated with Paxlovid (300 mg of nirmatrelvir with 100 mg of ritonavir) twice a day for 15 days and those who received a placebo, after 15 weeks (
Metformin is being considered as a potential treatment for long COVID because it modulates mitochondrial respiration, normalises dysregulated mTOR activity, reduces chronic inflammatory responses, supports vascular function, improves gut microbiome health and provides neuroprotective and epigenetic benefits (
Summary of registered clinical trials in progress.
| Study ID | Completion (Date) | Protocol reference/Trial title | Target sample size (N) | Intervention and dose | Treatment duration | Follow-up | Comparator | Primary outcome |
|---|---|---|---|---|---|---|---|---|
| Low-done Naltrexone ( |
||||||||
| NCT05430152 | 2025-08-16 | Low-dose naltrexone for post- COVID fatigue syndrome: a study protocol for a double- blind, randomised trial in British Columbia. |
160 | Low-Dose Naltrexone as a compounded capsule starting at 1 mg/day and increasing up to 4.5 mg/day (by wk. 4) | 16 wks | 16 wks | Placebo (to look exactly like LDN doses) | Change in Fatigue intensity by 4.7 points over using the Fatigue Severity Scale (FSS) |
| ACTRN1262300 1,042,639 | 2025-04-01 | Efficacy of Low Dose Naltrexone for the treatment of symptoms of Post COVID-19 Condition | 56 | Naltrexone Hydrochloride at low doses (low dose naltrexone [LDN], 3-6 mg/day) | 12 wks | 12 wks | Placebo | DSQ Symptom Inventory Questionnaire (Determine detectable change in symptom presentation and severity) |
| ACTRN1262400 1,162,505 | 2029-10-14 | Low dose naltrexone for the treatment of Myalgic Encephalomyelitis/Chro nic Fatigue Syndrome (ME/CFS) and long COVID Condition | 56 | Naltrexone-start 1.5 mg/day and will increase their dose by 1.5 mg/day weekly until their maximum dose is reached (target 4-6 mg/day for 12 wks) | 12 wks | 12 wks | Placebo | Change in the Transient receptor potential cation channel subfamily M member 3 (TRPM3) function |
| Antivirals ( |
||||||||
| NCT06055244 | 2025-05-15 | Amantadine Therapy for Cognitive Impairment in Long COVID (AmantadineLC) | 60 | Amantadine-100 mg 2 × per day | Unknown | 16 wks | Placebo | Overall cognitive functioning (self-assessed and objective), anxiety, depression, side-effects |
| NCT06234462 | 2025-06-01 | A Study of Amantadine for Cognitive Dysfunction in Patients With Long-Covid | 30 | Amantadine + standard care −100 mg 2 × per day | 4 wks | 6 wks | Standard of care = PT, OT, SLP, provider counselling, and/or pharmacologic interventions | Cognitive functioning (R BANS), FAS, Trails A& B, Digit vigilance test (DVT), cognitive subscale of modified fatigue impact scale (MFIS) |
| NCT05668091 | 2024-09-08 | A Decentralized, Randomized Phase 2 Efficacy and Safety Study of Nirmatrelvir/Ritonavir in Adults with Long COVID | 100 | Nirmatrelvir 2 × 150mg tablets 2 × per day + Ritonavir 1 × 100 mg capsule 2 × per day | 15 days | 28 days for primary | Placebo + Ritonavir (100 mg twice per day) | Primary- Physical Health summary; depression, physical function, pain interference, fatigue, sleep disturbance, and satisfaction with participation in social roles (PROMIS-29) |
| NCT05823896 | 2024-11-30 | ImPROving Quality of LIFe in the Long COVID Patient (PROLIFIC) | 219 | Oral nirmatrelvir (300 mg + ritonavir) (100 mg) 2 × per day | 15 days | Up to 90 days | Placebo/ritonavir (100 mg tablet of ritonavir twice per day) | Quality of life (EQ-5D-5L VAS scale), other secondary outcomes such as; hemodynamic response over time (active standing test), Composite Autonomic symptom score (compass31) |
| NCT05595369/NCT05965726 | 2025-03-13 | RECOVER-VITAL: Platform Protocol to Measure the Effects of Antiviral Therapies on Long COVID Symptoms (RECOVER-VITAL)/ RECOVER-VITAL: Platform Protocol, Appendix to Measure the Effects of Paxlovid on Long COVID Symptoms (RECOVER-VITAL) | 964 | Arm 1; Paxlovid 25 days (nirmatrelvir 300 mg, ritonavir 100 mg) bid × 25 Days | 25 or 15 days | Up to 90 days | Placebo control (ritonavir 100 mg + nirmatrelvir matching placebo for 25 days) | Change in Cognitive function (PROMIS cognitive function-8a), change in autonomic dysfunction (OHQ- orthostatic hypotension questionnaire), Change in exercise intolerance symptoms (DSQ-PEM), Other secondary outcomes such as serious adverse events |
| Arm 2; Paxlovid 15 days (nirmatrelvir 300 mg and ritonavir 100 mg) bid x 15 days then ritonavir 100 mg bid plus nirmatrelvir matching placebo × 10 days | ||||||||
| NCT06316843 | 2024–10 | Valacyclovir Plus Celecoxib for Post-Acute Sequelae of SARS-CoV-2 (PASC) | 59 | Arm 1–1,500 mg valacyclovir + 200 mg celecoxib −2 x per day | 10 wks | 12 wks | Placebo (placebo capsules taken 2 × per day) | Fatigue assessed with PROMIS Fatigue7a instrument |
| Arm 2–750 mg valacyclovir + 200 mg celecoxib-2 × per day | ||||||||
| NCT06161688 | 2025-12-31 | Ensitrelvir for Viral Persistence and Inflammation in People Experiencing Long COVID (PREVAIL-LC) | 40 | Ensitrelvir oral capsule- 375 mg on day 1, followed by 125 mg daily for 4 additional days | 5 days | Baseline, 10 days and up to 60 days post study | Placebo | Primary outcome is change in patient reported outcomes such as physical function, anxiety, depression, fatigue, sleep disturbance, social, and pain (PROMIS-29) |
| NCT06511063 | 2026–01 | Antiviral Clinical Trial for Long Covid-19 | 90 | Arm 1 (300 mg tenofovir) oral capsule 1 × day | 90 days | Day 180 | Placebo pill (once per day, oral capsule for 90 days) | Health status that contains 5 dimensions of mobility, self-care, usual activities, pain/discomfort, anxiety/depression) (EuroQol 5-Dimension 5-Level (EQ-5D- 5 L) Individuals own rating of overall health 0 -worst to 100- best (Visual Analogue Scale-VAS) |
| Arm 2 (300 mg Selzentry) Oral capsule 2 × per day | ||||||||
| Antihistamines ( |
||||||||
| ISRCTN10665760 | 2024–12 | STIMULATE-ICP: A pragmatic, multi- centre, cluster randomised trial of an integrated care pathway with a nested, Phase III, open label, adaptive platform randomised drug trial in individuals with long COVID | 1,555 | Loratadine 10 mg 1 × day + famotidine-40 mg 1 × day | 12 wks (84 days) | 12 and 24 wks | No drug (usual care) | Fatigue (FAS-Fatigue assessment scale) at baseline, 12 and 24 wks. |
| Metformin ( |
||||||||
| NCT06147050 | 2024–12 | Effect of Metformin in reducing fatigue in long COVID in Adolescents (REVIVE) | 16 | Metformin- 500 mg dose of extended- release formulation twice daily for a period of 30 days | 30 days | 90 days | Placebo twice daily | Mean pediatric Quality of life Multidimension al Fatigue Scale (PedsQL-MFS) |
| NCT06128967 | 2025-05-18 | A Multicentre, Adaptive, Randomized, double–blinded, Placebo-controlled study in participants with Long COVID-19: The REVIVE Trial (REVIVE) | 1,500 | Metformin extended- release oral tablet-750 mg | Unknown | 60 days | Placebo/Fluvoxamine Maleate-100 MG | Improvement on Fatigue Severity Score Scale (FSS) 60 days after randomization. |
| KCT0009342 | Unknown | Exploratory double-blind randomized placebo- controlled trial of Metformin and Ursodeoxycholic acid (UDCA) to treat post-acute sequelae of SARS-CoV-2 infection (PASC) | 396 | Metformin- 500 mg | 8 wks | Up to 6 mths | Placebo- 500 mg or Test medication 2- “300 mg Urusa (“urusodeoxy cholic acid”) or Placebo 300 mg | Change in PASC score symptoms |
| CTIS2024-511580- 28-00 | 2026-10-01 | RECLAIM: an adaptive platform trial for the evaluation of treatments for post-acute sequelae of SARS-CoV-2 infection (PASC) | Unknown | Metformin- oral 1,500 mg (max dose per day) *part of platform trial with Colchicine | 12 wks | 12 wks | Placebo | Patient- reported physical-health related quality of life (HRQoL) |
| Vagus Nerve Stimulation ( |
||||||||
| NCT05630040 | 2024-11-08 | Vagus Nerve Simulation for Long-COVID-19 | 40 | Portable VNS device daily | 6 wks | Baseline, week 2, week 5, week 8, week 12 | Sham VNS device | Composite Dysautonomia Symptom Score (COMPASS 31) |
| Colchicine ( |
||||||||
| ACTRN126210006378 42 | 2023-06-02 | A_multi-centre trial of colchicine vs. control to improve clinical outcomes in adults with long- SARS-CoV-2(COVID-19) | 1,000 | Colchicine 0.5 mg tablet twice per day given orally | 6 mths | 6 mths | Standard care | COVID-19 WHO score, Dyspnoea management questionnaire-30 |
|
|
2024–12 | STIMULATE-ICP: A pragmatic, multi- centre, cluster randomised trial of an integrated care pathway with a nested, Phase III, open label, adaptive platform randomised drug trial in individuals with long COVID | 1,555 | Colchicine 500 mcg taken twice daily by mouth (part of platform trial) | 12wks (84 days) | Up to 24 wks | Control (no drug) | Fatigue (FAS-Fatigue assessment scale) at baseline, 12 wks and 24 wks |
| CTRI/2021/11/038234 | Unknown | Colchicine to reduce coronavirus disease-19- related inflammation and cardiovascular complications in high-risk patients post-acute infection with SARS-COV-2-a study protocol for a randomized controlled trial. |
350 | Colchicine 0.5 mg once daily (< 70 kg) or twice daily (> = 70 kg) | 26 wks | 52 wks | Matched Placebo for 26 wks | Distance walked in 6 min at 52 wks from baseline |
| CTIS2024-511580-28-00 | 2026-10-01 | RECLAIM: an adaptive platform trial for the evaluation of treatments for post-acute sequelae of SARS-CoV-2 infection (PASC) | Unknown | Colchicine (Up to 1 mg/day) | 12 wks | 12 wks | Placebo | Patient- reported physical-health related quality of life (HRQoL) |
| Biologics and Monoclonal antibodies ( |
||||||||
| NCT05877508 | 2025-07-31 | Anti-SARS-CoV-2 Monoclonal Antibodies for Long COVID (COVID-19) (outSMART-LC) | 36 | AER002–1200 mg administered once by IV (intravenous infusion) | Once | Up to 1 yr | Placebo infusion by IV | Change in Patient- Reported Outcomes Measurement Information System (PROMIS)-29 Physical Health Summary Score from Baseline and Day 90 |
| ISRCTN46454974 | 2025–12 | A research trial to find out if tocilizumab helps adults with Long Covid feel better | 152 | Tocilizumab-162 mg subcutaneous injection (body weight <100 kg 162 mg fortnightly/body weight ≥100 kg 162 mg weekly for 12 wks) | 12 wks | 12 wks | Subcutaneous placebo for 12 wks | Health-related quality of life |
| NCT05926505 | 2025–08 | Safety and Efficacy of Anakinra Treatment for Patients with Post-Acute Covid Syndrome | 182 | Anakinra- 149 MG/ML (Prefilled Syringe Kineret) Anakinra is injected subcutaneously as 100 mg once daily for 4 wks. | 4 wks | Up to 2 years | Placebo- Placebo is injected subcutaneously once daily for 4 wks. | Score of PACS progression reversal |
| IVIg ( |
||||||||
| NCT06305780/NCT06305793 ( |
2026–03 | Randomized Trial of the Effect of IVIg Versus Placebo on long COVID Symptoms. | 380 | IVIg + coordinated care, IVIg + usual care, IVIg (Gamunex)- 2 g/kg monthly for 9 months (36 wks) | 9 mths | End of 12 mths | IVIg placebo + coordinated care Ivabradine + coordinated care, IVIg placebo + usual care, Ivabradine + Usual care, Ivabradin placebo + usual care | Change in Orthostatic Hypotension Questionnaire (OHQ)/Orthostatic Intolerance Questionnaire (OIQ) Composite Score |
| NCT05350774 | 2025-12-15 | Immunotherapy for Neurological Post-Acute Sequelae of SARS- CoV-2. |
45 | IVIg- 0.4 g/kg/day for 5 days | 5 days | 2 wks | Placebo | Proportion of participants with a clinically meaningful change in Health Utilities Index Mark 3 (HUI3) after receiving either IVIg or placebo at Week 2. |
| Co-enzyme Q10 ( |
||||||||
| NCT05373043 | 2028-10-31 | Long-term COVID and rehabilitation | 300 | Exercise + mitoquinone (synthetic form of coenzyme Q10) unknown dose | Unknown | 4 yrs | Exercise + Placebo | Change in flow mediated dilation (FMD), change in microvascular function (using passive leg movement-PLM), change in cerebral vascular endothelial function (using breath hold acceleration index-BHAI) |
ACTRN, Australian New Zealand Clinical Trials Registry number; COMPASS-31, Composite Autonomic Symptom Score; CTIS, Clinical Trials Information System (EU); CTRI, Clinical Trials Registry of India; DSQ, DePaul Symptom Questionnaire; DSQ-PEM, DePaul Symptom Questionnaire; Post-Exertional Malaise; EQ-5D-5L, EuroQol 5-Dimension 5-Level; FAS, Fatigue Assessment Scale; FSS, Fatigue Severity Scale; HUI3, Health Utilities Index Mark 3; ISRCTN, International Standard Randomised Controlled Trial Number; IVIg, Intravenous immunoglobulin; KCT, Korean Clinical Trial Registry identifier; LDN, Low-dose naltrexone; MFIS, Modified Fatigue Impact Scale; mth/mths, Month/months; NAC, N-acetylcysteine; NCT,
Theoretically, nicotine could help treat long COVID by competitively binding to nicotinic acetylcholine (nACh) and angiotensin-converting enzyme 2 (ACE2) receptors, displacing SARS-CoV-2 spike proteins and reducing the inflammatory response to the virus (
Vagus nerve stimulation (VNS) is a neuromodulation technique that involves stimulating the vagus nerve to modulate various physiological processes. In the context of Long COVID, VNS is being investigated due to its potential to regulate inflammation and autonomic function, which may address multiple symptoms associated with the condition (
Antihistamines may improve long COVID symptoms by blocking both histamine H1 and H2 receptors and reducing mast cell activation, which is thought to play a role in the pathophysiology of long COVID, thereby reducing brain fog and fatigue. There were no systematic reviews or RCTs investigating the efficacy of antihistamines as a treatment for long COVID. A single non-randomised controlled trial examined the effects of a combination of fexofenadine (180 mg/day) and famotidine (40 mg/day) on long COVID symptoms (
Guanfacine is a highly selective α2A-adrenergic receptor agonist that is thought to strengthen pre-frontal cortex connectivity and reduce neuro-inflammation and has been used to treat cognitive disorders such as attention deficit hyperactivity disorder (ADHD) (
Colchicine is commonly used as an anti-inflammatory medication in the treatment of gout and may help treat long COVID symptoms, in particular pericarditis (inflammation around the heart) and pleuritis (inflammation in the lungs) through a similar mechanism (
Nattokinase is an enzyme produced during the fermentation of soybeans to create ‘natto’, a traditional Japanese food. It has been speculated that Nattokinase may be useful in managing a variety of long COVID symptoms because in-vitro studies have demonstrated that it degrades fibrinaloid microclots and the SARS-CoV-2 spike protein in cell cultures (
Intravenous immunoglobulins (IVIg) are derived from donor human plasma and are used to treat antibody deficiencies and auto-immune conditions. Because IVIgs are thought to modulate immune responses, they may be useful in managing a variety of long COVID symptoms (
Monoclonal antibodies (mAbs) were originally created and used as treatments for acute COVID infections. However, they could potentially treat a variety of long COVID symptoms by clearing SARS-CoV-2 virus reservoirs by targeting the spike protein of the virus and reducing inflammation by modulating the immune response to the virus (
Coenzyme q10 (CoQ10) is a supplement that has been widely used for a range of clinical applications and may be a potential treatment for long COVID fatigue because of its role as an antioxidant and in cellular energy function (
Multi-component intervention packages combine core treatment elements like symptom management (e.g., pain), sustainable increases in physical activity, sleep regulation and pacing, and optional modules addressing issues such as managing breathlessness, mood or cognition. They are usually tailored to the individual’s symptoms and are delivered by a multidisciplinary team often including physical therapists, psychologists and a general practitioner, each of whom focus on one or more symptoms. Evidence from five RCTs suggests that multicomponent interventions can be safe and effective at improving overall quality of life and dyspnoea in individuals with long COVID. There is no strong evidence to suggest that they improve other physical, mental or cognitive symptoms (
Most of the exercise training interventions for long COVID consist primarily of aerobic and/or strength training with some also incorporating flexibility and balance. In total, 16 RCTs looked specifically at exercise training in long COVID patients (aerobic training k = 3, strength training k = 3, combined exercise k = 8 and pilates k = 2), demonstrating that exercise interventions can be effective in improving fatigue, quality of life, physical performance and mental health in individuals with long COVID (
This narrative review provides an overview of the available evidence for several potential long COVID treatments that are being considered for future clinical evaluation. In line with recent reviews, the findings highlight the heterogeneity of interventions, ranging from dietary supplements and rehabilitation to complementary therapies. The findings also reinforce the persistent uncertainty around long COVID treatments, despite a rapidly evolving body of evidence. Only six out of 14 of the prioritised treatments have any long-COVID specific RCT-based evidence. The remainder rely on biological plausibility or low quality evidence (case studies).
The treatments reviewed included a range of pharmacological and non-pharmacological approaches aiming to alleviate either symptoms or targeting the underlying biological mechanisms of long COVID. The most common mechanism of action across treatments for long COVID appears to be the reduction of inflammatory pathways and viral reservoirs which might suggest that other treatments that have similar effects may be useful (
For clinicians, this research offers a timely overview of the current status of the available evidence for treatments prioritised by clinicians and people with lived experience. Although some treatments such as exercise training show promise and seem feasible and acceptable, there is insufficient high-quality evidence to make informed recommendations for clinicians and people living with long COVID. For funders, researchers and other stakeholders, this review highlights critical evidence gaps, including the need for randomised clinical trials that investigate treatments that are acceptable to and aligned with lived experience.
Although the systematic reviews and RCTs were identified via a systematic search, other study designs were identified through a more pragmatic search to identify the best available, most recent evidence. Furthermore, the interventions summarised were chosen by clinicians and people with lived experience based on their clinical relevance and acceptability. Consequently, this review does not provide a comprehensive list of all potential long COVID treatments. It must also be noted that findings are not intended to be used as clinical guidance – this would require a more robust review of the evidence, and a multidisciplinary and systematic consideration of the clinical and patient context using well established methods to assess the quality of the evidence.
Finally, the overall quality of evidence is very low, due to the lack of high quality RCTs and systematic reviews, underscoring the need for further rigorously designed, well-powered clinical trials.
In this review, we summarised the evidence for, acceptability, feasibility and safety for 14 stakeholder-prioritised treatments for long COVID. Only six of these have any RCT evidence and most are supported by limited or indirect data. The next step is well-designed trials that use standardised patient centered outcomes, ensure adequate follow-up and consider implementation. This review supports the development of such trials rather than providing guidance in clinical settings.
SB: Methodology, Writing – review & editing, Writing – original draft, Formal analysis. TA: Writing – review & editing, Formal analysis, Investigation. SC: Funding acquisition, Supervision, Writing – review & editing, Methodology, Conceptualization. MB: Formal analysis, Writing – review & editing. PG: Funding acquisition, Writing – review & editing, Conceptualization, Supervision. OB: Writing – review & editing, Project administration, Methodology, Supervision, Investigation.
We thank the members of the consumer and clinician panels who contributed to the prioritisation workshops and the investigators from the HEAL COVID and OUTPOST projects for their guidance during the evidence synthesis.
The author(s) declared that this work was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
The author(s) declared that Generative AI was used in the creation of this manuscript. Generative AI was used to simplify the summaries presented to people with lived experience as part of the prioritisation workshop materials.
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