Clinical Research Directory

Virtual Reality in Intensive Care Unit: Patient Satisfaction, Clinical and Functional Outcomes, Feasibility

Background: Virtual reality is recognized as a progressive technology with the potential to enhance the rehabilitation process. Immersive virtual reality-based treatments can improve motor outcomes in physical rehabilitation, reduce stress caused by the intensive care unit environment and maximize patients' recovery processes. Objective: To analyze the efficacy of rehabilitation using immersive virtual reality on patient satisfaction and experience, functional and clinical outcomes and the feasibility of its application during the hospitalization period in an intensive care unit (ICU). Methods: This is a randomized controlled clinical trial involving ICU patients aged 18 years or older, with an estimated ICU stay of ≥ 72 hours, the ability to understand and follow verbal instructions and no diagnosis of psychotic disorders, visual impairment, or hearing loss. Patients will be divided into two groups: one undergoing traditional physiotherapy rehabilitation - control group (CG), and the other receiving physiotherapy using immersive virtual reality (IVR group). The following evaluations will be conducted: mobility condition, physical and psychological discomfort, estimated physical activity level, occurrence of delirium, cognitive decline screening, functionality classification, motivation level, patient experience, sense of immersion in the virtual reality environment, patient satisfaction during the rehabilitation process, occurrence of adverse events, and protocol feasibility. Data will be presented in graphs and tables. Results will be considered statistically significant at a 5% significance level (p ≤ 0.05), and all analyses will be performed using SPSS Statistics version 22. Expected results: The investigators expect to find evidence that rehabilitation using immersive virtual reality can promote and enable a more pleasant and less traumatic experience during the patient's hospitalization, with greater satisfaction and adherence to the proposed rehabilitation, in addition to being an effective tool to optimize patients' functional and clinical outcomes.

AI Based Muscular Ultrasound to Assess Intensive Care Unit-acquired Weakness

The aim of this observational case-control study is to investigate, whether artificial intelligence can detect ultrasound-derived imaging characteristics typical for intensive care unit-acquired weakness. The main questions it aims to answer are: 1. Is the evaluation of specific parameters of neuromuscular ultrasound using AI-based image analysis suitable for detecting and monitoring critically ill ICU patients with ICUAW? 2. Do the results of AI-based ultrasound image analysis correlate with: (A) the severity of ICUAW (B) the visual grading of muscle echogenicity (C) the 30- and 90-day-outcome?

Skeletal Muscle Regeneration in Survivors of Critical Illness: How to Prevent Satellite Cell Failure?

Modern intensive care enables patients to survive insults that in the past would have been supralethal. Nonetheless, increased number of survivors suffer from failed functional outcomes associated with prolonged muscle weakness and fatiguability. Whilst alterations of skeletal muscle biology that occur during critical illness slowly disappear over the period of months, muscle weakness remains. Recent pilot studies have shown that muscle weakness is associated with loss and alteration of satellite skeletal muscle cells, which are supposed to proliferate and repair damaged muscle tissue. The pathogenesis of this phenomenon has not been fully understood. In this grant project, we will study function and structure of satellite cells and their organelles (particularly mitochondria) using both classical bioenergetics and advanced microscopic techniques. Satellite cells will be isolated from biopsies taken from critically ill patients with developed muscle weakness in the acute and protracted phase of a disease and after 6 months. In time points, an ultrasound examination of muscle mass will be performed, and metabolism will be assessed using insulin clamps. In an in vitro experiments, we will test also effect of nutritional and anabolic factors and drugs, commonly used in ICU, on satellite cells. In a control branch, cells will be isolated from skeletal muscle of volunteers undergoing elective hip replacement surgery. Results of this study could significantly contribute to understanding of mechanisms leading to ICU acquired muscle weakness and to identify therapeutic strategy in future.