View clinical trials related to ICU Acquired Weakness.
Filter by:Patients admitted to the ICU due to critical illness often experience physical, mental, cognitive, or social issues. Research indicates that inadequate physical recovery is associated with lower handgrip strength, and hand function in ICU patients is lower compared to healthy individuals. To address this, a Virtual Reality (VR) exergame was developed to aid rehabilitation. This study aims to investigate the effect of a 4-week VR-exergame intervention on handgrip strength, hand and arm functionality, balance, mobility, and support needs in ICU patients staying for 48 hours or longer. It is a multicenter mixed-methods randomized controlled trial involving adult ICU patients. The intervention involves a 4-week VR-exergame program. Main study parameters include handgrip strength, hand and arm functionality, range of motion, balance, mobility, and support needs. The burden and risks associated with participation are minimal, as VR-based exercises are deemed safe and voluntary. Overall, the study aims to assess the effect of incorporating VR-based rehabilitation into standard care for ICU patients.
This study aims to investigate how sepsis and shock can impair microcirculation in intensive care unit (ICU) patients, which can lead to long-lasting muscle weakness/dysfunction or ICU-Acquired Weakness (ICU-AW) and exercise limitations.
Intensive Care Unit Acquired Weakness (ICUAW) describes muscle weakness that occurs in around 40% of patients during an intensive care stay. The morbidity and mortality of these patients is significantly increased over a 5-year period. The aim of this study is to investigate the combined effect of early enteral high-protein nutrition and early muscle activation on muscle atrophy in critically ill patients. The study will include 40 patients (20 intervention, 20 observation) with requirement for enteral nutrition at time of inclusion. In the intervention group the maximum possible level of mobilization is carried out and muscles are activated twice a day using neuromuscular electrical stimulation (NMES). The nutrition plan of the intervention group is based on the applicable guidelines for intensive care medicine with exception of increased protein intake. The control group receives therapy without deviating from the standard according of the DGEM guideline. The study aims to show that the decrease in muscle mass is significantly less than in the control group (primary hypothesis) via ultrasound of the rectus femoris muscle and in case of given consent muscle biopsy. As secondary hypothesis it is examined whether the combination of early high protein intake and muscle activation improves muscle strength and endurance.
Due to medical advances and quality of care, mortality in adult intensive care units (ICUs) has decreased significantly in recent years, leading to a significant increase in the number of patients with high rehabilitation needs on discharge from the ICU. A specific management by a multidisciplinary team has been set up since 2017 at the Geneva-ICU for long-stay patients (hospitalised ≥ 7 days). This study aim to assess whether an optimization of the nutritional therapy coupled with an early mobility during and after the ICU stay allows an improvement in the muscle function at hospital discharge compared to patients receiving the standard care.
Ventilator-induced diaphragmatic dysfunction and intensive care unit (ICU)-acquired weakness are two consequences of prolonged mechanical ventilation and critical illness in patients with acute respiratory distress syndrome (ARDS). Both complicate the process of withdrawing mechanical ventilation, increase hospital mortality and cause chronic disability in survivors. During transition from controlled to spontaneous breathing, these complications of critical illness favor an abnormal respiratory pattern and recruit accessory respiratory muscles which may promote additional lung and muscle injury. The type of ventilatory support and positioning may affect the muscle dysfunction and patient-self-inflicted lung injury at spontaneous breathing onset. In that regard, ARDS patients with ventilator-induced diaphragmatic dysfunction and ICU-acquired weakness who are transitioning from controlled to partial ventilatory support probably present an abnormal respiratory pattern which exacerbates lung and muscle injury. Physiological-oriented ventilatory approaches based on prone positioning or semi recumbent positioning with abdominal binding at spontaneous breathing onset, could decrease lung and muscle injury by favoring a better neuromuscular efficiency, and preventing intense inspiratory efforts and high transpulmonary driving pressures, as well as high-magnitude pendelluft. In the current project, in addition to perform a multimodal description of the severity of ventilator-induced diaphragmatic dysfunction and ICU-acquired weakness in prolonged mechanically ventilated ARDS patients, prone positioning and supine plus thoracoabdominal binding at spontaneous breathing onset will be evaluated.
The overarching goal of the proposed study is to determine the trajectories of physical recovery and cellular markers involved with the underlying failure to recover muscle after critical illness, while exploring which characteristics are associated with sustained physical disability. This proposal will examine muscle pathophysiology carefully aligned with physical function outcomes in order to longitudinally assess the recovery, or failed recovery, of muscle function in participants after critical illness: 1. to examine the recovery of muscle and physical function in ICU survivors through longitudinal assessments 2. to investigate the underlying cellular markers and mechanisms of muscle recovery in ICU survivors 3. to determine which cellular markers contribute to physical disability in ICU survivors up to 1 year after hospital admission
Muscle dysfunction can be lead to poor outcomes moreover ICU muscle weakness recovery are not correctly described. The investigators aimed to assess the ability for quadriceps or respiratory muscles to repeat an effort at a maximal loading.
Multicenter, prospective, randomized controlled trial providing mobile health supported physical rehabilitation to 120 patients who have been critically ill with COVID-19 and who complete at least one exercise session.
Background & Significance. Children with congenital heart disease (CHD) have experienced improved postoperative survival shifting the focus away from minimizing mortality to curtailing morbidities. Critical illness following cardiac surgery induces catabolism which may impact functional status. Catabolism, a state in which protein breakdown exceeds protein synthesis, can lead to lean body mass (LBM) breakdown. LBM loss has been associated with poor clinical outcomes. Muscle ultrasound (mUS) has been utilized to measure LBM changes and the functional status score (FSS) was developed to assess functional status changes in children following hospitalization. The ability to identify LBM loss acutely and its association with FSS changes may lead to earlier interventions to preserve LBM and aid in outcome prediction. Specific Aims & Hypotheses. Specific Aim 1 is to identify the percent change in LBM by mUS during the first postoperative week in children following complex cardiac surgery. Specific Aim 2 is to evaluate the relationship between percent change in LBM during the first postoperative week and the FSS at discharge and 6 and 12-month follow-up in children with CHD following complex cardiac surgery. The investigators hypothesize children with CHD following complex cardiac surgery will experience a decline in LBM and that there is a direct relationship between the change in LBM and postoperative FSS follow-up. Study Design & Methods. The investigators are conducting a single-center, prospective, observational cohort study. Consecutive children (> 3 months and < 18 years of age) with CHD undergoing biventricular conversion will be enrolled. Patients will undergo a baseline mUS and FSS at the time of the index operation. Interval mUS will be obtained on the third and seventh postoperative day. Discharge mUS and FSS will be obtained and a remote FSS will be requested by the family at 6 and 12-months postoperatively. Demographics, pertinent laboratory, concomitant medications, nutrition and ultrasound variables will be collected. Outcomes. The primary outcomes will be change in LBM during the first postoperative week and change in FSS at 6 and 12-month follow-up in children following complex cardiac surgery. Change in LBM will be defined as a percent change in cross-sectional area of the quadriceps muscle layer thickness (QMLT). Change in FSS will be significant if the score drops 3 points or more from baseline at postoperative follow-up.
We conducted a retrospective study of critical ill patients who used ECMO during their ICU stay. ICU-AW was diagnosed at the time when patients discharged and had a Medical Research Council (MRC) sum score < 48 out of a maximal score of 60. We divided patients to ICU-acquired weakness group and no ICU-acquired weakness group and compared their clinical characteristics. Baseline characteristics and therapy details were collected from the case report forms and inspection reports. Univariable analysis and logistic regression analysis were used to analyze clinical characteristics of individuals and to find risk factors of ICU-AW.