View clinical trials related to Hand Injuries.
Filter by:The study aimed to investigate the effects of early sleep after action observation and motor imagery (AOMI) training sessions on manual dexterity in patients with hand immobilization after surgical fixation for metacarpals and phalanges fractures. Fifty-one patients with hand immobilization for surgical fixation of IV or V metacarpals or first phalanges fractures will be randomized into AOMI-sleep (n=17), AOMI-control (n=17), and Control (n=17) group. AOMI-sleep and AOMI-control groups will perform an AOMI-training before sleeping or in the morning respectively, while Control group will be asked to observe landscape video-clips. Participants will be assessed for manual dexterity, hand range of motion, hand disability and quality of life at baseline before and after the training and at 1 month after the training end.
The hand is the basic functional organ of the human body and is responsible for complex tasks such as grasping and catching. It also plays an important role in a person's daily life, self-care activities and business life. When the flexor tendon system, which is necessary for the effective use of the hand, is damaged, it can cause physical, socioeconomic deterioration, mood disorders and permanent disabilities in the individual. Treatment of flexor tendon injuries after appropriate surgical repair ıt includes an intensive rehabilitation program. In this study, it was aimed to investigate the early rehabilitation results of patients who underwent a rehabilitation program after Zone II flexor tendon injury by comparing the improvements in joint range of motion, pain, functionality and quality of life with other zone injuries.
The study has three main phases. The first phase included A. Adjustment of research tools. Phase B. will examine the efficacy of the cultural intervention. Phase C. Follow-up study will be conducted after three, six, and nine months.
Single-center nonrandomized single-arm early feasibility study of participants with soft tissue trauma in the hand. Prior to enrolling participants with hand injuries, the safety of continuous glove use for up to 96 hours without a glove replacement will be assessed on healthy volunteers. Injured participants will be on study for up to 7 weeks depending on when the final glove is removed. Screening: Prior to surgery and through 72 hours post-surgery to identify eligible patients Treatment with Glove: Treatment begins with initial application of the ReHeal Glove and can last up to 7 days (with dressing changes every 48-72 hours unless more frequent changes are requested by the treating physician.) Follow-up: Up to 6 weeks after final removal of glove to ensure complete wound healing.
The purpose of this study is to review the clinical outcomes following hand ligament reconstruction surgery using allograft (cadaveric) knee collateral ligaments. Currently, there is no standard procedure or devices used for hand ligament reconstruction surgery, although most techniques use some form of autograft (patients' own tissue) for the reconstruction. We believe that the use of allograft ligaments in reconstruction may eliminate the pain associated with procuring the patients' own tissue for the procedure, and prove to be a viable and preferred alternative to the multiple techniques currently used. The main procedures of this study include wrist and hand ligament reconstruction surgery (for wrist scapholunate (SL) ligaments, thumb ulnar collateral ligaments (UCL), and finger proximal interphalangeal (PIP) joint collateral ligaments) using allograft ligament, and subsequent follow up appointments where measurements and questionnaires will be completed to evaluate how hand function is doing after surgery.
Steroids are often prescribed for their anti-inflammatory effects in patients with musculoskeletal injuries. Studies have shown that steroids may reduce pain and swelling, but their effects on range of motion and functional outcomes have not been illustrated. With this study, we aim to evaluate the effect of steroids on range of motion and functional outcomes in non-operatively managed musculoskeletal injuries of the hand.
Distal radius fracture is the most common upper extremity fracture with peak incidence among older women after the fifth decade of life. Proprioception is one constituent of a complex Sensory motor control process. Proprioception requires the reception and central integration of incoming afferent signals. Although various sensory and motor deficits have been correlated with significant functional impairment after wrist trauma, limited research exists on the effects of proprioception and multi sensory training after distal radius fracture.
Hand edema following hand surgery is a common yet devastating side effect that can lead to early stiffness, prolonged rehabilitation and diminished function. These factors can reduce a patient's quality of life; mounting to an overall delay in recovery, return to work and daily activities. Conventional edema therapy includes cryotherapy, external compression, active and passive exercises and various types of massage. However, there is little evidence to suggest these modalities are effective. Tranexamic acid (TXA) is an antifibrinolytic that has been used in surgical disciplines for decades to aid in reducing intraoperative blood loss and consequent transfusions. Recently, the use of TXA for curbing post-operative edema and ecchymosis has shown promising results, however, its use in hand surgery has not been studied.
Microvascular partial toe transfer for reconstruction of traumatic amputation of the digits
Recovery after a hand or wrist injury often includes wearing a cast, or limiting daily activities to help with healing, but this may lead to deconditioning. Previous research suggests resistance training with the healthy arm during this period could help improve recovery of the injured arm: this is called cross-education. Mirror visual feedback (e.g. watching the movement of an uninjured hand in front of a mirror hiding the injured hand to create the illusion both hands are moving) is another cross-body method which can improve recovery after stroke, and prevent or reduce pain in complex regional pain syndrome. Both of these treatments may work because they activate a specific area in the brain: using them together might strengthen the effects. However, this has never been studied after injury. The investigators are proposing a pilot study to see if it is possible and helpful to use these treatments in combination to improve recovery of grip strength and reduction of pain and disability. The investigators will use this information as a foundation to tell us how to run the best study to test these ideas in ways to be confident in the results.