View clinical trials related to Wounds and Injuries.
Filter by:Appropriate management reduces the mortality of severe trauma victims. This is based on a pre-hospital medical assessment of severity, the initiation of life-saving treatments at the pre-hospital level, and referral to a hospital with human and material resources adapted to the patient's severity. The objective of this research project is to show that the 28-day mortality after severe trauma is lower in a structured health system, compared to a non-structured system.
Prospective observations on safety of the herbal medicines regarding liver and kidney injuries at inpatient setting of four sites in South Korea which are located at each quadrant of the country. In a previous study (PMID 28634823), six women presented liver injuries by herbs and similar findings were also reported. That knowledge has been developed to design the observations of females (19-80 ages) at least 2 weeks' hospitalization with weekly routine lab tests to obtain the occurrence of liver or kidney injuries and the profiles on micro biomarkers throughout the hospitalization period, and then, the follow-up test will be conducted in outpatient setting.
The purpose of this study is to examine the effectiveness of mobility training using the Ekso robotic exoskeleton with functional electrical stimulation (FES) in persons affected by spinal cord injury; designated AIS classification A, B, C, or D. Traditionally, a person with an American Spinal Injury Association Impairment Scale (AIS) "A" injury, walking training is not performed. Even with AIS B, C and D injuries, although walking training may be appropriate, a person may not walk as much as needed to see an improvement due to environmental and staff limitations. The Ekso is a tool to give walking training to patients. The investigators aim to see if utilizing these technologies will affect recovery; specifically in sensation and muscle activity below the level of the injury as well as the ability to walk. The Ekso is a wearable, battery- operated exoskeleton that assists with walking. The Ekso has motors at the hip and knee joints to provide assistance that may be needed with walking. All motion is initiated either through body weight shifts or the use of an external controller. The Ekso robotic exoskeleton has been approved by the Food and Drug Administration as a powered exercise device for rehabilitative purposes such as this study. Currently, the Ekso is approved for people with spinal cord injuries from T4-L5 given bilateral arm strength of 4/5. With injuries from C7-T3, individuals must have AIS classification of D with bilateral arm strength of 4/5. For this study, it is possible that Ekso GT will be used outside of the current FDA approval if the injury level is C7-T3 and the person is classified as an AIS A, B or C injury level. Functional electrical stimulation (FES) will be used in conjunction with the robotic exoskeleton. FES involves using surface electrodes placed on the skin like a sticker over key leg muscles that will be stimulated in the normal walking pattern as a person walks in the device.
The purpose of this research study is to evaluate the effectiveness of "RehaCom," a computerized treatment for memory deficits, in a 16-session, interactive course. Following a manualized approach, the Rehacom modules will be used for the repeated application of the content acquired during 1-on-1 memory strategy training. The goal is to improve face/name, list and verbal memory of patients who survived a moderate to severe traumatic brain injury.
The aim of this study is to investigate the incidence of lingual nerve injury and related factors in difficult intubation cases. Demographic data of difficult intubation cases and body mass indices, thyromental and sternomental distances, mallampati classification, neck circumference, maximum mouth opening be recorded.Numbness of the tongue and metallic taste will be questioned
The affectedness of the motor control of the upper limb, particulary, the hand and/or fingers, appears in many neurological diseases, what is going to impact on the functionality of the subject. The use of new technologies in the rehabilitation environment, has the target to reduce the impact on the disabling conditions. So that, the goal of this investigation is to evaluate the system use effectiveness of the Leap Motion Controller® in the treatment on the upper limb on patients with neurological disease.
Over 85,000 Canadians live with a spinal cord injury (SCI). The vast majority experience chronic pain from neuropathic or musculoskeletal origins, with many reporting the pain to be more physically, psychologically and socially debilitating than the injury itself. Currently, pharmaceuticals are the front line treatment recommendation for SCI pain, despite having many side-effects and giving minimal relief. Alternatively, studies conducted in controlled lab and clinical settings suggest that exercise may be a safe, effective behavioural strategy for reducing SCI-related chronic pain. Two ways in which exercise may alleviate pain are by reducing inflammation and increasing descending inhibitory control. To date, no study has tested the effects of exercise, performed in a home-/community-setting, on chronic pain in adults with SCI. Furthermore, information on the exercise dose required to alleviate chronic SCI pain is virtually non-existent, making it impossible for clinicians and fitness trainers to make evidence- informed recommendations regarding the types and amounts of exercise to perform in order to manage SCI pain. Recently (2018), an international team published two scientific SCI exercise guidelines: one to improve fitness and one to improve cardiometabolic health. These scientific guidelines have been translated into Canadian community SCI exercise guidelines and provide the exercise prescription for the proposed study. The investigators' overarching research question is: can home-/community-based exercise-prescribed according to these new SCI exercise guidelines and supported through a theory-based behavioural intervention- significantly reduce chronic pain in adults with SCI?
Spinal Cord Injury (SCI) leads to alterations in brain structure and function by spinal nerve damage, secondary inflammatory responses, and by the consequences of living with paralysis and neuropathic pain. Physical inactivity due to lower body paralysis rapidly leads to loss of muscle, and risk of heart disease. The leading cause of death after a spinal cord injury is cardiovascular disease, and just a year after injury, those with SCI have a peak exercise capacity half that of the unfit general population. The good news is that aerobic exercise reduces the risk of chronic metabolic and cardiorespiratory diseases, reduces inflammation and pain, and increases mood and quality of life. Exercise can also reduce brain inflammation, enhance endogenous analgesia, and increases the size of the hippocampus. The issue is that muscle paralysis in SCI restricts the ability to achieve the levels of exercise that is necessary for broad analgesic, anti-inflammatory and neuroprotective benefits. Arm exercise can have some effects on heart and lung capacity, but the small muscle mass is insufficient to produce more than modest aerobic work. With functional electrical stimulation (FES), leg muscles that are paralyzed can be made to contract, thereby allowing more of the body to be exercised. The full rowing stroke is produced by both the (stimulated) legs and arms, increasing the active muscle mass and resulting in an aerobic work-out that is intensive enough to improve heart, lung, and - maybe - brain function. In this clinical trial of sub-acute spinal cord injured subjects, the investigators will study how 12 weeks of FES-RT, in comparisons to 12 weeks of wait-list, changes pain, brain structure, endogenous opioid function and brain inflammation. The investigators will measure changes using positron emission tomography and magnetic resonance imaging. The investigators hypothesize a decrease in pain interference, an increase in hippocampal volume, increased endogenous opioid transmission in the periaqueductal gray, and decreased hippocampus neuroinflammation.
Multicenter, randomized, single-blind, parallel-controlled non-inferiority assessment for safety and efficacy of rotator cuff injury and/or shoulder instability surgery
Why? There is not much information in the UK on how well patients who sustain major trauma function afterwards. Major trauma is defined as significant injuries with a calculated 'injury severity score' (ISS) over 15. The ISS is calculated based on how many parts of the body are injured and how badly injured these are, up to a maximum score of 75 (fatal). We feel that learning more about how these people cope afterwards, and what influences this will allow us to improve the care we can deliver in the future, which will hopefully lead to better outcomes. What? We propose to implement the FIT (Functional outcomes In Trauma) study to assess how well patients function physically, psychologically and socially, and get back to activities of daily living, work and participation in recreational activities following major trauma. Who? Major trauma patients: 2 cohorts: prospectively going forwards in time (from baseline to 12 months after trauma) and retrospectively going backwards in time (patients between 2-10 years after trauma). Where? Leeds General Infirmary. How? We will do this by collecting data from questionnaires completed by patients (also known as PROMS, or Patient Reported Outcome Measures), using an online questionnaire service developed at the University of Leeds, called QTool. These will offer the participants the chance to tell us how they are doing across lots of areas, with both tick-box multiple choice questions and open-ended questions to explain how they are doing and what influences this. We will also interview a random selection of patients in further detail to discuss how their trauma has affected them, how they found the study, how we could improve it. Afterwards we will send participants a copy of what we have learnt from the study and aim to publish it in a scientific journal. Timeline/Phase overview: The FIT Study will consist of 2 phases. Phase 1 will last for 2 years in total (12 months for prospective study cohort recruitment and 12 months follow-up for these patients) during which time data will be collected from the retrospective cohort as well. Following this there will be a full analysis of the data, after which phase 2 of the FIT Study will begin. Patients enrolled into phase 1 of the study will be given the option of consenting to being contacted annually to complete the same set of online PROMs, which will comprise phase 2 of the study. We will also continue active recruitment into both prospective and retrospective arms of the study in phase 2. We plan to continue data collection on an annual basis up to 10 years post trauma in phase 2 of the study for patients in both cohorts. We hope to incorporate elements of the FIT Study into future routine care with what we learn from the FIT Study, and develop our own unique Patient Reported Outcome Measure tool, with the overall aim of improving patient care and outcomes.