Clinical Trials Logo

Muscle Atrophy or Weakness clinical trials

View clinical trials related to Muscle Atrophy or Weakness.

Filter by:
  • Completed  
  • Page 1

NCT ID: NCT04913935 Completed - Clinical trials for Thumb Osteoarthritis

Investigation of Thenar Muscles Morphometric Parameters in Patients With TMC OA

Start date: September 5, 2019
Phase:
Study type: Observational

In this study, investigators aimed to investigate the morphometric parameters tenar muscles and joint configuration in patients with trapeziometacarpal osteoarthritis (TMC OA) osteoarthritis stages, thenar muscle parameters, radial subluxation rate, functional level and hand dexterity.

NCT ID: NCT04450615 Completed - Core Stability Clinical Trials

Core Exercises Effects on Muscle Imbalances

Start date: May 20, 2020
Phase: N/A
Study type: Interventional

This study aims in investigating the effects of a core muscles' strengthening program on core muscles' atrophy and contraction ability. Twenty healthy adults recruited and randomly assigned to either a 5-week training group developed to activate and strengthen local trunk muscles or a control group. The training program includes isometric bridging exercises from various positions and dynamic exercises for lumbopelvic stability. Core muscles' thickness will be assessed at rest and contracting conditions, prior and after the intervention, using ultrasonography.

NCT ID: NCT04333186 Completed - Critical Illness Clinical Trials

Expiratory Muscle Function in Critically Ill Ventilated Patients

EMFIC
Start date: February 15, 2017
Phase:
Study type: Observational

Inspiratory muscle weakness develops rapidly in ventilated critically ill patients and is associated with adverse outcome, including prolonged duration of mechanical ventilation and mortality. Surprisingly, the effects of critical illness on expiratory muscle function have not been studied. The main expiratory muscles are the abdominal wall muscles, including the external oblique (EO), internal oblique (IO) and transversus abdominis muscles (TRA). These muscles are activated when respiratory drive or load increases, which can be during e.g. exercise, diaphragm fatigue, increased airway resistance, or positive airway pressure ventilation. The abdominal wall muscles are also critical for protective reflexes, such as coughing. Reduced abdominal muscles strength may lead to decreased cough function and thus inadequate airway clearance. This will lead to secretion pooling in the lower airways, atelectasis, and ventilator associated pneumonia (VAP). Studies have shown that decreased cough function is a risk for weaning failure and (re)hospitalization for respiratory complications. Further, high mortality was found in patients with low peak expiratory flow. Considering the importance of a proper expiratory muscle function in critically ill patients, it is surprising that the prevalence, causes, and functional impact of changes in expiratory abdominal muscles thickness during mechanical ventilation (MV) for critically ill patients are still unknown. Ultrasound is increasingly used in the ICU for the visualization of respiratory muscles. In a recent pilot study the investigators confirmed the feasibility and reliability of using of ultrasound to evaluate both diaphragm and expiratory abdominal muscle thickness in ventilated critically ill patients (manuscript in preparation). Accordingly, the primary aim of the present study is to evaluate the evolution of abdominal expiratory muscle thickness during MV in adult critically ill patients, using ultrasound data.

NCT ID: NCT02174029 Completed - Clinical trials for Muscle Atrophy or Weakness

Serial Daily Diaphragm Ultrasounds in Ventilated Patients

Start date: June 2014
Phase: N/A
Study type: Observational

When a person is put on a breathing machine the investigators think that the breathing muscles can get weaker. The investigators are not sure how quickly this happens but in some people this leads to problems when they try to breathe on their own without the breathing machine. The diaphragm is at the bottom of a person's chest separating their lungs from what is in their belly and it is a very strong muscle. In fact, it is main muscle that one uses for breathing. An ultrasound machine is a painless way to see what is happening beneath the skin. It is safe and easy to do. Using an ultrasound the investigators are planning to measure how thick the diaphragm is and how much it changes while a person is on a breathing machine in the ICU. Getting a better understanding of this condition could lead to improved treatments that might help support patients who require a ventilator for breathing. The investigators hypothesis is that patients for whom the breathing machine is doing all of the work of breathing, will have their diaphragm thickness gradually decrease and changing to a breathing modem mode where they have to put in more effort the diaphragm thickness will start increasing again.