Intensive Care Units are specialized and high-cost hospital units equipped with advanced technology, designed for the treatment and continuous monitoring of critically ill patients who are at risk of losing, or have already lost, some or all of their vital bodily functions. These units provide twenty-four-hour monitoring of vital signs, operate with a multidisciplinary healthcare team, and have privileged status in terms of patient care (1). The most common reasons for admission to Intensive Care Units include acute heart attacks, severe breathing difficulties, heart bypass surgeries, congestive heart failure, strokes or bleeding within the brain, cardiovascular system problems, pneumonia, widespread infections called sepsis, diabetic ketoacidosis, gastrointestinal bleeding, and other serious health conditions (2). Among these, the most frequent reason for admission is respiratory failure that requires mechanical support to assist or take over breathing (3). The period of critical illness can last from a few hours to several months depending on the underlying disease process and how the patient responds to treatment, and it is associated with high rates of death and serious health problems (4).
Patients treated in Intensive Care Units face various problems that either develop during their stay or exist beforehand and continue. These problems include muscle weakness, cognitive difficulties, psychological challenges, worsening physical function, and reductions in quality of life and the ability to perform daily activities (5). Bed rest or immobilization is often a necessary part of treatment in Intensive Care Units (3). Prolonged immobility can cause many clinical complications that may be severe and last a long time, leading to physical limitations and negatively affecting quality of life over the long term (6). Research has identified bed rest as harmful because it can cause complications such as fluid buildup in the lungs, collapse of parts of the lungs, loss of bone density, muscle wasting, instability of blood vessel regulation, constipation, pain, pressure sores, joint contractures, and blood clots (7).
Predictive scoring systems are clinical tools used to evaluate the severity of illness in Intensive Care Unit patients and to predict their prognosis, especially the risk of death (8). These clinical scoring systems help classify patient risk levels, predict health outcomes, and improve other clinical management processes. Although these scoring tools assist physicians in managing patients, they are not routinely used in everyday clinical practice mainly because they are complex and require specific expertise and training (9).
Some of the common scoring systems used for adult patients in Intensive Care Units include the Acute Physiology and Chronic Health Evaluation, the Simplified Acute Physiology Score, the Mortality Prediction Model, the Organ Dysfunction and Infection System, the Sequential Organ Failure Assessment, the Multiple Organ Dysfunction Score, the Logistic Organ Dysfunction Model, and the Three-day Recalibrating Intensive Care Unit Outcomes system (10).
The Acute Physiology and Chronic Health Evaluation scoring system was developed in nineteen eighty-one by the George Washington University Medical Center and is known as one of the most widely used and recognized scales for determining the severity of acute illnesses. The version known as Acute Physiology and Chronic Health Evaluation version two was created for different research and clinical audit purposes and continues to be used extensively to assess disease severity in critically ill patients in Intensive Care Units (11, 12). It is a highly selective and accurate measurement tool that can serve as a standard in Intensive Care Units by enabling evaluation of standardized mortality ratios (12).
Loss of muscle strength and muscle weakness are well known to negatively impact patients in Intensive Care Units. This loss of muscle strength can delay or hinder the recovery of physical function in patients who survive Intensive Care Unit treatment. Additionally, patients who develop muscle weakness due to long stays in Intensive Care Units have been shown by ultrasound measurements to have reduced thickness and cross-sectional area of peripheral muscles compared to patients without muscle weakness (13, 14). However, the relationship between the course and severity of disease and respiratory muscle strength, peripheral muscle thickness, and muscle tone in Intensive Care Unit patients is not yet fully understood. Determining how the course and severity of disease affect respiratory muscle strength, biomechanical properties of peripheral muscles, and muscle structure is critically important for establishing effective physiotherapy and rehabilitation strategies in Intensive Care Units.
The aim of this study is to investigate the relationship between disease severity and respiratory muscle strength, peripheral muscle structure, and the biomechanical properties of peripheral muscles in patients treated in Intensive Care Units. This study will be conducted using a cross-sectional and observational research design.
