Early rehabilitation in critical care (eRiCC): functional electrical stimulation with cycling protocol for a randomised controlled trial
- Selina M Parry1,2,
- Sue Berney2,
- René Koopman3,
- Adam Bryant1,
- Doa El-Ansary1,
- Zudin Puthucheary4,
- Nicholas Hart5,
- Stephen Warrillow6,
- Linda Denehy1
- 1Department of Physiotherapy, School of Health Sciences, The University of Melbourne, Melbourne, Australia
- 2Department of Physiotherapy, Austin Health, Melbourne, Australia
- 3Department of Physiology, The University of Melbourne, Melbourne, Australia
- 4Department of Asthma, Allergy and Lung Biology, Institute of Health and Human Performance, University College London, Kings College London, London, UK
- 5Guy's and St Thomas’ NHS Foundation Trust and King's College London, NIHR Comprehensive Biomedical Research Centre, London, UK
- 6Department of Intensive Care, Austin Health, Melbourne, Australia
- Correspondence to Selina Parry;
- Received 29 July 2012
- Accepted 14 August 2012
- Published 13 September 2012
Introduction Intensive care-acquired weakness is a common problem, leads to significant impairment in physical functioning and muscle strength, and is prevalent in individuals with sepsis. Early rehabilitation has been shown to be safe and feasible; however, commencement is often delayed due to a patient's inability to co-operate. An intervention that begins early in an intensive care unit (ICU) admission without the need for patient volition may be beneficial in attenuating muscle wasting. The eRiCC (early rehabilitation in critical care) trial will investigate the effectiveness of functional electrical stimulation-assisted cycling and cycling alone, compared to standard care, in individuals with sepsis.
Methods and analysis This is a single centre randomised controlled trial. Participants (n=80) aged ≥18 years, with a diagnosis of sepsis or severe sepsis, who are expected to be mechanically ventilated for ≥48 h and remain in the intensive care ≥4 days will be randomised within 72 h of admission to (1) standard care or (2) intervention where participants will receive functional electrical muscle stimulation-assisted supine cycling on one leg while the other leg undergoes cycling alone. Primary outcome measures include: muscle mass (quadriceps ultrasonography; bioelectrical impedance spectroscopy); muscle strength (Medical Research Council Scale; hand-held dynamometry) and physical function (Physical Function in Intensive Care Test; Functional Status Score in intensive care; 6 min walk test). Blinded outcome assessors will assess measures at baseline, weekly, at ICU discharge and acute hospital discharge. Secondary measures will be evaluated in a nested subgroup (n=20) and will consist of biochemical/histological analyses of collected muscle, urine and blood samples at baseline and at ICU discharge.
Ethics and dissemination Ethics approval has been obtained from the relevant institution, and results will be published to inform clinical practice in the care of patients with sepsis to optimise rehabilitation and physical function outcomes.
Trial registration Australian and New Zealand Clinical Trials Registry ACTRN12612000528853.
Early rehabilitation is now advocated for individuals who are at risk of developing intensive care unit acquired weakness (ICUAW).
Can FES(functional electrical stimulation)-assisted cycling or cycling alone minimise muscle mass and strength reductions, and improve discharge physical function, compared with standard care in patients with sepsis?
What are the cellular and molecular mechanisms responsible for muscle changes in this patient population, and can these be attenuated using FES cycling or cycling alone?
This protocol outlines a randomized controlled trial (RCT) that will investigate the effectiveness of an FES-assisted cycling intervention and cycling alone, commencing within 72 h of ICU (intensive care unit) admission compared to standard care.
The results of this trial will provide data to guide the early rehabilitation treatment of patients with sepsis.
Muscle biopsies and biomarker analyses will provide insights into the effects of sepsis, and an intensive care admission, and early rehabilitation on intracellular signalling pathways and histochemical changes responsible for muscle mass losses.
Strengths and limitations of this study
This is the first time that FES-assisted cycling has been investigated within the ICU within 72 h of admission with sepsis.
This study combines bench-side research (biopsies and biomarker analyses) with patient-centred outcomes (strength and physical function).
It is a single centre trial so results may need to be generalised with caution.
Intensive care-acquired weakness (ICUAW) is a common problem following an ICU admission1–3 and is associated with prolonged hospitalisation, delayed weaning and increased mortality.4–6 Up to 25% of patients requiring mechanical ventilation (MV) for greater than 7 days develop ICUAW,1 and this figure may rise to 50–100% in the septic population.7 ,8 Long-term follow-up studies of survivors of critical illness have demonstrated significantly impaired health-related quality of life9 ,10 and physical functioning11–14 up to 5 years after ICU discharge, with weakness being the most commonly reported physical limitation.12 While survival has been a main focus of intensive care research, there is a paradigm shift to investigating methods to improve other patient-centred outcomes.15 There has been an increased awareness worldwide of the potential impact and benefit of early rehabilitation in the ICU.15–19 Early rehabilitation in the form of mobilisation has been shown to be safe and feasible;20–24 however, it relies on the patient being co-operative, and to have sufficient cardiorespiratory reserve and medical stability25 to participate in therapy.
Muscle mass is known to reduce by at least 1.6% per day,26 with a 16–20% reduction in muscle mass within the first week in critically ill individuals with severe sepsis,27 indicating that interventions to attenuate muscle wasting in this initial stage may be beneficial. The musculoskeletal system is a highly plastic and adaptive system, responding quickly to changes in the demands placed upon it.3 ,28 ,29 The pathogenicity and molecular mechanisms for ICUAW have primarily been extrapolated from animal and in vitro muscle wasting models3 ,30–33 with ubiquitin−proteasome-mediated breakdown postulated to be primarily responsible for the muscle loss observed in critically ill individuals.30 ,34–36 Local and systemic inflammatory processes, which occur in critically ill individuals, are thought to lead to a disruption in the balance between muscle protein synthesis and protein breakdown, leading to an overall reduction in muscle mass and force generation capacity.30 ,37 Increased circulating inflammatory cytokines (eg, TNF-α and IL-1β) may drive mitochondrial oxidative stress and increase intracellular calcium, which are postulated to trigger muscle proteolytic pathways30 ,38 and may interfere with insulin signalling leading to anabolic resistance,39 and contribute to electrophysiological inexcitability of the muscle.40 Recent clinical trials in critically ill individuals have demonstrated a reduction in muscle myofibre size with preferential proteolysis of the thick myosin filaments,41 ,42 with one trial demonstrating a dramatic increase in protein degradation of up to 160%.42 Currently, the pathogenesis of ICUAW is poorly understood given limited research within human clinical trials.2 ,30 Establishing the cellular and molecular mechanisms responsible for loss of muscle mass and strength is essential to help develop future medical and physical therapies.
There is growing interest in the use of assistive technologies to enable patients to commence therapy early in an ICU admission.43 Supine cycle ergometry, which can be utilised passively, actively (by patient effort) or active assisted (using electrical stimulation)16 has been studied in ICU within one trial with promising results.16 However, the intervention did not begin until at least 1-week post admission and there were no data reporting frequency of active versus passive cycling.16 Neuromuscular electrical stimulation (NMES) creates passive (ie, non-volitional) contraction of skeletal muscles through the use of low-voltage electrical impulses delivered through to the skin to underlying muscle via surface electrodes.43 It can be commenced early, without the need for patient participation and has been shown to prevent skeletal muscle atrophy in healthy individuals44 and improve physical function and strength in chronic disease populations, such as heart failure and chronic obstructive pulmonary disease.45 To date, studies within the ICU have involved stimulation of only isolated muscle groups such as the quadriceps, or peroneal muscles, in a resting non-functional position using NMES, with conflicting findings.27 ,46–50 Further rigorous research needs to be conducted to determine the optimal stimulation settings, and efficacy of these interventions particularly post ICU on muscle strength and physical function, which is being investigated in one trial currently underway in the USA.51
Functional electrical stimulation (FES) is different to NMES, as it recruits muscles in functional patterns stimulating them in a similar way to how the muscles would ‘normally’ contract under volitional control in healthy individuals. For FES, the majority of the literature to date has been developed within the chronic stroke52 and spinal cord injury (SCI) populations.53 Alternating recruitment of several muscle groups in a functional activity, such as cycling has been demonstrated in a chronic SCI population to improve the length of time a contraction can be sustained, prior to reaching the point of fatigue.54 This may enable patients to train for a longer period of time, thereby enhancing the training effect. FES-assisted cycling may influence muscle strength and physical function not only at ICU discharge, but also at acute hospital discharge. This trial seeks to examine the combined effect of FES-assisted cycling on muscle mass, strength, and physical function, and compare this with cycling alone, and standard care.
The primary objectives are to:
Evaluate the effectiveness of FES-assisted cycling and cycling alone compared with standard care on muscle mass/cross-sectional area, strength and physical function, in individuals admitted to ICU with sepsis.
Evaluate the effectiveness of FES-assisted cycling compared with cycling alone, on muscle mass, muscle architecture, strength and physical function in individuals admitted to ICU with sepsis.
The secondary objectives are to:
Establish the intracellular signalling pathways and histochemical changes responsible for muscle mass losses in individuals with sepsis.
Inform decisions about outcome measures and power calculations for future studies.
Hypotheses for the primary aims
Patients who undergo FES-assisted cycling and cycling alone compared with standard care will have improved muscle mass/cross-sectional area, strength and physical function.
Patients who undergo FES-assisted cycling when compared with cycling alone will have greater improvement in muscle mass, strength and physical function.
Patients in the intervention group will have improved activity of anabolic signalling pathways when compared with patients receiving standard care as demonstrated from biomarker analysis.
This is an assessor blinded randomised controlled trial (RCT) which will be conducted at Austin Health in Melbourne, Australia.
Inclusion and exclusion criteria: Eighty participants in ICU (Austin Health, Melbourne, Australia) meeting the eligibility criteria will be recruited. Inclusion Criteria: (1) ≥18 years, (2) expected MV>48 h with diagnosis of sepsis or severe sepsis as defined by ACCP Consensus Conference Criteria55 and (3) predicted ICU LOS ≥4 days. Exclusion Criteria: (1) known primary systemic neuromuscular disease or intracranial process at admission; (2) lower limb amputation/s; (3) unable to perform study physical outcome measures premorbidly due to condition impairing mobility; (4) assessed by medical staff as approaching imminent death or withdrawal of medical treatment within 36 h; (5) pregnancy; (6) BMI>40; (7) presence of external fixator or superficial metal in lower limb; (8) open wounds or skin abrasions at electrode application points; (9) presence of pacemaker or implanted defibrillator; (10) transferred from another ICU after >2 days of consecutive MV; (11) platelets<40 000 and INR>1.6 (for biomarker subgroup).
This study will take place in a single centre tertiary 20-bed ICU over an 18-month period. The ICU has a throughput of 2100 patients per year with 200 patients/year who are both septic and requiring MV for >48 h.
Recruitment and randomisation
Patients meeting the above criteria will be invited to participate. Written informed consent from the patient, next of kin (NOK) or substitute decision maker will be sought. Participants will be asked to provide ongoing consent when able. Participants will be randomly assigned [1 : 1] to receive either standard care or the intervention using offsite-independent randomisation. Concealed allocation will be performed using sequentially numbered opaque sealed envelopes only accessible by research personnel with no involvement in the trial. Intervention arm: leg allocation will be randomly allocated [1 : 1] to FES-assisted cycling or cycling alone.
This trial involves a two-tier consent process first to the FES-assisted cycling intervention and then additionally to biomarker analysis and muscle biopsies with a nested subgroup (n=20) within the primary trial. Details of all participants who refuse consent to muscle biopsy will be recorded. Information regarding screening and flow through this trial will be reported according to the CONSORT (Consolidated Standards of Reporting Trials) Extended Non-Drug guidelines.56 This trial has been approved by the Human Research Ethics Committee, Austin Health and registered with the Australian and New Zealand Clinical Trials Registry Identifier: ACTRN12612000528853.
The planned flow of participants throughout the study is provided in figure 1. Once consent is obtained, and prior to randomisation; participants will be referred to a physiotherapist who will administer baseline testing of muscle mass/cross-sectional area (CSA) using diagnostic ultrasound (US) and body composition analysis. Once the patient is awake, a blinded outcome assessor will assess baseline strength and physical function once per week. ‘Wakefulness’ is defined as being able to follow >3 of 5 commands as assessed by the De Jonghe's readiness scale1 with a Riker Sedation Agitation Scale (SAS) of 3–5.57 Biomarker assessment involving muscle biopsies, urine and blood analyses will be assessed at baseline and ICU discharge only. Attrition will be monitored and reasons for withdrawal will be recorded in each trial arm within figure 1.
Both groups will receive usual medical and nursing care in the ICU and ward settings. In the ICU, physiotherapy will be administered according to a standardised protocol, developed from a previous trial at the same institution. Patients in both arms will undergo usual care physiotherapy including respiratory and mobilisation/rehabilitation.20 Mobilisation activities (including those used for the benefit of the respiratory system) will be provided for up to but not more than 15 min. Where possible the level and type of exercise delivered, will be prescribed using the initial PFIT results for each individual patient as per standard care.58 Details of physiotherapy treatment will be recorded but not protocolised on the acute hospital ward.
The intervention will start within 72 h of ICU admission, continuing until ICU discharge. Participants will undertake up to 1 h of supine cycling daily, ≥5 times weekly using a supine cycle ergometer (RT-300 supine model Restorative Therapies, Ltd, Baltimore, Maryland, USA) attached to a six-channel stimulator (SAGE stimulator, Restorative Therapies Ltd, Baltimore, Maryland, USA) and two RT50 wireless stimulator channels. Surface electrodes will be applied to the gluteal, hamstrings, quadriceps and calf muscles on both legs. However, the cycling only leg will not have the electrodes switched on (sham).
The intensity of muscle stimulation will be delivered at a level able to cause visible contractions (confirmed by palpation if uncertain) in all muscle groups without causing undue pain or discomfort to the participant. Pain levels will be closely monitored during and post each intervention session (box 1). If no contractions can be elicited this will be recorded, but the treatment continued, and palpation for contraction assessed at 5 min intervals. FES intensity will be gradually increased to a maximum of 140 mA; with pulse duration of 300−400 μs; frequency between 30 and 50 Hz; and a pedal cadence between 30 and 45 rpm. Stimulation parameters will be adjusted to achieve the best possible muscle contraction for the patient. Once the patient is more alert, and able to participate, they will be provided with standardised encouragement to engage in therapy. To increase the intervention workload, resistance (N m) will be increased incrementally and cycling cadence up to a maximum of 45 rpm. If a participant is readmitted to intensive care, the intervention will be re-instigated until discharge to the acute ward.
Safety guidelines for exercise
Safety guidelines: exercise should not be delivered or should be ceased when:
Patient mean arterial blood pressure <65 or below target pressure.
Patient heart rate is <50 or >140 beats/min or new arrhythmia develops (including ventricular ectopics or new onset atrial fibrillation).
Patient requires >30 µg of noradrenaline or comparable inotropic or vasopressor support.
Patient complains of new onset chest pain.
Patient becomes pale or sweaty and/or patient specifically requests to stop due to feeling acutely unwell.
Presence of extracorporeal membrane oxygenation or intra-aortic balloon pump.
PEEP>15 cm H2O.
Respiratory rate >35 breaths/min sustained for >60 s.
spO2 falls >10% below resting level or <85% for >60 s.
Numerical rating scale (NRS) pain level remains >7 for 5 min despite adjusting stimulation intensity. Pain levels will be monitored using NRS if patient is awake at commencement and 5 mins into the exercise session. If the patient is intubated we will use standardised assessment of pain including facial grimacing, ventilator dysinchrony, and agitation levels to monitor pain levels during exercise.
FiO2, Fraction of inspired oxygen; mm Hg, millimetres of mercury; µg, micrograms; NRS, Numerical Rating Scale; PEEP, Positive end expiratory pressure; spO2, saturation of peripheral oxygen.
While participants and intervention physiotherapist cannot be blinded to group allocation, outcome assessors and data analysts will be blinded to group allocation. The success of blinding will be assessed using a short outcome assessor questionnaire for each time point and the number of ‘unblinding’ episodes will be recorded. If an assessor becomes unblinded, an alternate assessor who is ‘blinded’ will continue to do the measures for that particular individual.
Table 1 provides a summary of the outcome measures and the time-points at which they will be assessed. All primary outcome measures will be measured at baseline; weekly while in ICU; at ICU discharge; and acute hospital discharge.
Baseline descriptive data collection will include age, gender, social, working and smoking history, admission diagnosis, hand/leg dominance, comorbidities as determined by the Functional Comorbidity Index and Charlson Comorbidity Index, severity of illness scoring and SAS Score. Additionally number of days of sedation and nutritional parameters, will also be recorded. ICU LOS, ICU free days at day 28, MV hours, tracheostomy requirement, incidence of ICU readmission, acute hospital LOS, discharge destination and mortality will also be recorded.
Primary outcome measures
Bioelectrical impedance spectroscopy (BIS): Participants will undergo measurement of body composition using multi-frequency BIS machine (ImpediMed SFB7, ImpediMed Ltd, Brisbane, Australia). This will enable calculation of total body water, extracellular and intracellular fluid as well as fat-free mass, and an estimate of muscle mass.59 Measurements will be taken in triplicate with participants in the supine position after single use dual tab gel electrodes have been placed on one foot and one hand on the same side.60 All data will be uploaded onto the BioImped software (BIS) for subsequent analysis. The reliability of this device in both the critically ill and healthy populations has previously been established61 and numerous investigators have established the validity of the BIS in detecting within subjects change over time in septic and postsurgical populations.62 ,63
Diagnostic two-dimensional (2D) ultrasonography (US) of quadriceps muscle: Rectus Femoris and Vastus Intermedius CSA and thickness will be measured using diagnostic US (Voluson e BT09 Ultrasound, GE Healthcare, Yokogawa Medical Systems Ltd, Japan). Participants will lie in supine with their leg in passive extension and neutral rotation. A water-soluble transmission gel will be applied to the US head to allow acoustic contact, without depressing the dermal surface. The scanning head will be applied perpendicular to the long axis of the thigh on its anterior surface, approximately three-fifth distance from anterior superior iliac spine to the superior patellar border.64 The point will be marked for consistency of US probe location. Measures will be made in triplicate and averaged. The same operator who is experienced in the measurements will perform all US examinations. For supplementation of muscle thickness measurements, circumference of the thigh will be assessed using a tape measure at the US measurement site. Reliability and validity of ultrasonography have previously been established both in septic and other medical populations.65–67
Medical Research Council Scale (MRC): manual muscle testing will be scored using the six point MRC scale.68
Hand-held dynamometry (HHD): Hand grip and quadriceps strength (supine with 5-inch bolster under knee to enable flexion)69 will be assessed using HHD bilaterally using a Commander PowerTrack II Dynamometer 1500 (Banner Therapy Ltd, Asheville, North Carolina, USA) and a Jamar Dynamometer (Sammons Preston Rolyan, Bolingbrook, Illinois, USA), respectively. HHD has established reliability and validity.69 ,70
Will be assessed using several different methods:
‘PFIT’ (Physical Function Independence Test)71
‘FSS-ICU’ (Functional Status Score in ICU)72
The ‘six minute walk test’ (6-MWT) is a commonly used test, which measures the distance that a patient can walk quickly in 6 min over a 25 m flat hallway. It is both self-paced and sub-maximal. The 6 MWT has previously been used in the ICU population. This test will only be performed at acute hospital discharge.73
Secondary outcome measures
Participants who consent to participation will also be approached for consent to biomarker assessment involving muscle biopsies, blood and urine samples. Within the intervention arm as previously described, one leg undergoes cycling alone and the other FES-assisted cycling. Therefore, muscle biopsies will be collected from both lower limbs in the intervention arm, and in one lower limb in the standard care arm, to allow comparison across the groups. Biomarker assessment will be performed at baseline, and at ICU discharge (where possible the ‘ICU discharge’ measure will occur 24 h post final intervention exercise session).
Using an aseptic technique, under local anaesthetic injected into the skin and fascia, muscle biopsies (100–200 mg of tissue) will be obtained from the vastus lateralis muscle, 10 cm above the patella. Prior to biopsies being performed, senior medical staff will review anticoagulation profiles, and using the Bergstrom percutaneous needle technique under suction74 will perform biopsies. Once the tissue has been extracted, part of the biopsy sample (20–50 mg) will be dissected carefully, freed from any visible non-muscle material, embedded in Optimal Cutting Temperature (OCT) compound and immediately frozen in liquid nitrogen-cooled isopentane and stored at −80°C until histochemical analyses. The remainder of the biopsy (100–150 mg) will be immediately frozen in liquid nitrogen and stored at −80°C, until further analyses. Histological assessments of muscle structure and infiltration of inflammatory cells, will be performed using H&E staining, and examination of muscle fibre-type-specific changes in cross sectional area, oxidative capacity, substrate stores, satellite cell activation and key proteins regulating protein synthesis and breakdown (mTOR, AMPK, MURF-1 and MAFbx).75 mRNA and protein expression levels and phosphorylation status of key signalling proteins in the regulation of inflammation will be determined using RT-PCR and standard immune-blotting techniques, respectively.76
Twenty-four hour urine samples will be collected for analysis of urinary creatinine, 3-methylhistidine (3-MH) and urea levels. The samples will be stored at −80°C until analysis. 3-MH will be analysed using high-performance liquid chromatography (HPLC).
Venous blood (15 ml) will be collected at each time point and processed to obtain plasma and serum for subsequent analyses. Stored plasma and serum will be analysed using ELISA methods for IGF-1, IL-1β, IL-6, IL-10, IL-18 and TNF-α. Blood levels of C-reactive protein (CRP), urea and creatinine will be retrieved from the standard intensive care nursing charts over a 24-h period. HPLC will be performed to analyse vitamin D levels, serum amino acid concentration levels and 3-MH levels.
All physiotherapists providing intervention and outcome measurements are experienced ICU clinicians trained in safety and basic life support. Written manuals of protocols and safety guidelines will be made available to all research personnel. Criteria for commencing and ceasing exercise or outcome measurement are outlined in box 1.
If any adverse event occurs either during, or up to an hour following intervention or outcome measurement, the chief investigators will be notified. Serious adverse events are defined in this trial as ‘adverse events’, which results in death, cardiac arrest or stroke. These events will be reported to the Austin Health HREC. A data monitoring committee will examine trial safety by reviewing any adverse events at regular intervals. Research personnel to identify potential safety, recruitment, and treatment issues will review data process indicators based on the consort diagram monthly.
Sample size calculation
The sample size calculation is informed by data from Burtin et al16 using the HHD improvement±SD for quadriceps strength of 0.54±0.76 N/kg. Using α=0.05 and power=0.80 the total required sample size is 64 cases. Allowing for 14% in hospital mortality and dropouts the sample size has been increased to 80 cases. For biomarker analyses (primarily muscle biopsy) the sample size calculation is based on prior trials detecting changes in muscle protein synthesis and associated signalling following exercise, nutritional and pharmacological interventions (increase in signalling >20% with SD in signalling of 2%).77 ,78 Using α=0.05 and power=0.80 the required sample size is 18 cases. To account for dropouts and mortality we have increased this sample size to 20 cases.
All data will be entered into a purposefully designed database and exported to IBM SPSS Statistical software package (SPSS Inc, V.20, Chicago, Illinois, USA) for analyses. Descriptive statistics will first be used to examine the distribution for the two groups comparing baseline scores, to describe mean outcomes, and test whether parametric test assumptions have been met. Analyses will be by intention to treat. Statistical significance will be set at p<0.05 (two-tailed). Possible differential attrition will be assessed by comparing baseline characteristics of those who withdraw or die against those who remain in the trial. Linear mixed modelling will be used to assess the treatment effects. Imputation of missing data will not be undertaken. Adjustment will be undertaken if significant imbalance is evident in baseline covariates and in this case results of both the adjusted and unadjusted results will be described.79 As a secondary analysis mean change in scores, 95% CIs, and comparison with minimal clinically important differences in outcomes will be presented.
Ethics and dissemination
The Austin Health HREC has granted ethical approval for this trial. Trial results will be disseminated widely, through peer-review journal manuscripts and scientific conference presentations. The investigators will submit trial progress summaries to all sponsors of the trial on a regular basis.
The trial will determine whether FES-assisted cycling, or cycling alone compared to standard care will improve muscle mass, strength and physical function. The cellular and molecular mechanisms, responsible for the observed muscle mass and strength changes will be examined using biomarker analyses.
ICU-AW is a well-recognised clinical problem especially in individuals with sepsis. The effects of this syndrome have been shown to last for many years, with physical function one of the most affected patient outcomes. This research is innovative in that it combines both clinical and basic sciences to evaluate the mechanisms of change together with measuring patient-centred outcomes. It will be the first interventional trial to evaluate the effectiveness of FES-assisted cycling and cycling alone on muscle mass, architecture, strength and physical function. The important primary outcomes for the patient are expected to be improved or maintained strength, and physical function. Given the potentially devastating effects of a critical illness on the survivors and their families,15 gaining improved strength and physical function will be critical outcomes for all ICU survivors. The study design will allow future decisions to be made about sample sizes and primary outcomes to inform future research. The evaluation of an early rehabilitation programme involving FES-assisted cycling, which can commence in the critical period where the majority of muscle reductions occur, may provide direction for the development of appropriate rehabilitation in survivors of ICU.
This research is being undertaken by SP as part of a doctoral qualification with the support of a National Health and Medical Research Council Dora Lush Scholarship (#103923) and previously the Stella Mary Langford Scholarship. The authors would like to acknowledge the companies; Restorative Therapies and GE Healthcare for their support with training. The authors thank the staff of the physiotherapy and intensive care departments at Austin Health, Melbourne, Australia, for their ongoing support of the project.
Contributors All authors contributed to the study design, method and writing. SP, LD, SB, RK, NH, AB and SW helped to develop the successful grant proposals, which support the study. SW and NH were involved in providing advice on safety; monitoring and ethical issues and LD will chair the data monitoring committee. SP, AB and DE contributed to the ultrasound protocol and analysis component of the trial. RK, ZP, NH and SW have specifically contributed to the biomarker analysis component of the trial. SP drafted the manuscript. All other authors critically revised it for important intellectual content. All authors contributed to and approved the final version of the manuscript for publication.
Funding Australian Intensive Care Foundation, Austin Medical Research Foundation and Society of Critical Care Medicine Vision Grant (United States). None of the funding bodies have any influence on the study design, collection or data analysis or publication of results.
Competing interests None.
Ethics approval Austin Health Research Ethics Committee.
Provenance and peer review Not commissioned; internally peer reviewed.
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