View clinical trials related to Tibial Fractures.
Filter by:The current method of incision localization in many surgical procedures requires a doctor to reference a medical image, such as an X-ray, to judge where on the body an incision should be made. However, the precise information of the scan is not shown on the patient's skin. Surgeons commonly use palpation to locate the point of incision. They may feel for the area directly or find landmarks under the skin and estimate the location from there. The following factors further complicate palpation: overweight patients, foreign bodies that are difficult to feel for under the skin, fractures with little displacement, or locations under dense muscles. These difficulties are compounded for new surgeons, since palpation is a skill derived through experience. In many circumstances the surgeon only needs to know where to insert the tool or place the incision - they do not necessarily need to know the depth of the area of interest. If palpation proves ineffective, they may be forced to use fluoroscopy. By referencing the fluoroscopy image the surgeon moves a radiopaque marker, such as their surgical tool, closer to the area of interest. Fluoroscopy is time-consuming, and exposes medical personnel and the patient to radiation. Many fluoroscopic images may be required in a single procedure. By identifying the efficacy of this new medical device, "Target Tape", there is the potential outcome of making smaller incisions, faster localization, a reduction in fluoroscopy use and a reduced chance in surgical error and the associated costs. Target Tape is a non invasive device that is in a grid or ruler format that is placed against the subject's skin. The grid/ruler pattern will then appear on the medical imaging scan. Standard surgical skin ink is then used to place these markings in a defined pattern on the skin. This pattern mimics the Target Tape grid or ruler pattern. The medical practitioner can correlate these skin markings to the medical scan image to make their incisions in more accurate locations.
Consenting patients with proximal tibia fractures will be randomized to 10 degree or 21 degree cryotherapy sleeves. Time to discharge and complications will be monitored. Primary outcome measure: Cost of Treatment (based on length of stay) Secondary outcome measures: Satisfaction/pain relief and narcotic requirement
The purpose of our study is to evaluate the use of recombinant human bone morphogenetic protein 2 (RhBMP-2) as compared to standard ICBG in the treatment of severe open tibia fractures with a critical size bone defect (at least one centimeter in length compromising at least 50% of the circumference of the bone).
The purpose of this clinical outcomes collection study is to analyze the effect of the EBI OsteoGen™ Direct Current Stimulator upon surgical reconstruction of tibia nonunion (no visible progressive signs of healing) fracture in a prospective database.
The purpose of this study is to determine the effect of low-intensity, pulsed ultrasound on tibial fractures treated with intramedullary nailing.
The researchers propose a prospective, randomised partially-blinded study to investigate the clinical and radiological outcome, effect on quality of life and socio-economic impact of non-union of diaphysary tibial fractures treated with BMP-7 in adjunct to fresh frozen allograft, in comparison to treatment with allograft together with DBM (demineralised bone matrix).
The primary objective of this study is to assess whether a single dose of rhBMP-2/CPM administered at the fracture site via percutaneous injection, in combination with standard of care, accelerates fracture union and return to normal function in subjects who have a closed diaphyseal tibial fracture when compared to standard of care alone.
The purpose of this study is to apply Anodyne therapy to active duty soldiers, who have shin splints, to evaluate healing time and effectiveness.