View clinical trials related to Head Trauma.
Filter by:Patients with skull defects after craniotomy for example tumor resection, head trauma, stroke, need a reimplantation of the bone afterwards. For some circumstances, their own bone cannot be reimplanted due to infection, tumor infiltration, damage to the bone, or aseptic bone necrosis. In these cases a Patient Specific Implant (PSI) needs to be designed to fit into the patient`s skull defect. The design of the PSI is based on the preoperative CT-scan of the patient`s head with the skull defect, the imaging data set is uploaded and processed with IPlanNet software by BrainLab®. With the help of the software, a 3D model of a negative mould of the PSI is designed and printed. In the operation room, the PSI is fabricated under sterile conditions using the PSI mould. The design of the PSI mould with the help of IPlanNet is demanding and takes some few hours depending on the complexity of the case to be designed. In certain cases the accuracy of the fabricated PSI mould is not optimal, so that the surgeon intraoperatively has to adapt for the inaccuracy to achieve the best cosmetic and functional results at the expense of the operation duration, a known risk factor for postoperative wound infection and other perioperative complications. Therefore, the investigators have developed an automated computer-based algorithm for PSI design (CAPSID). With the help of this tool, an accurate PSI and its corresponding mould can be calculated and designed based on the preoperative CT scan of the patient within 5-15 minutes and the corresponding mould can be printed. This step is automated and thus, independent of the neurosurgeons experience and skills in 3D processing software. The mould can be used for intraoperative fabrication of the implant under sterile conditions in the common way as described above. The possible advantages of the clinical establishment of this procedure would be a higher accuracy of the PSI compared to the conventional PSI fabrication method with better cosmetic results, lower costs and faster availability and production leading to shorter waiting time for the patient, and as a consequence of the higher accuracy leading to shorter operation time, with a reduction of risk of operative adverse events for the patient. Furthermore, the proof of practicability of this new method, could lead to new concepts in the field of Computer-based Patient Specific Implants in modern medicine in general.
The investigators prospectively want to use the Infrascanner in patients with ischemic stroke, patients with brain surgery, patients with brain tumors, patients with intracranial hemorrhage and patients with a normal CT scan of the brain as part of a diagnostic work-up after head trauma or headache to determine to positive and negative predictive value of the Infrascanner in these different settings.
The purpose of the study is to determine the effectiveness of the helmet-less tackling training (the HuTT Technique) intervention to reduce head impacts in high school football players and to gain an understanding of the neurocognitive effects of repetitive head impacts in football. The investigators hypothesis is that the HuTT Technique will result in a reduced frequency and magnitude of helmet impacts than the control group measured by a head impact measurement system. Also, the investigators hypothesize the HuTT Technique group will demonstrate less changes in neurocognitive scores in the mid and post season evaluations compared to the control group. Head impacts will be measured using the SIM-G impact monitor made by Triax Technology. The SIM-G impact monitor measures the location, magnitude, and direction of every head impact in real time and is stored on a protected cloud-based system. The sensor is worn by each athlete in a headband or skullcap. Neurocognitive function will be measured using the Immediate Post-concussion Assessment and Cognitive Testing (ImPACT) test. The test is used as a tool to determine baseline neurocognitive function and is used in comparison if an athlete was to be injured to ensure he/she returns to baseline. ImPACT measures memory (verbal, visual, working), processing speed and reaction time using a variety of tests. Subjects will be recruited from local high school football teams and will include freshman, sophomores and juniors. Since the study is expected to run for 2 years, seniors will not be eligible for participation. The target is to recruit at least 150 total subjects. All subjects will be equipped with a new helmet that is fitted to their head and a headband that will be used to hold the head impact telemetry sensor. In addition, all subjects will take an ImPACT test preseason, midseason and postseason. At the conclusion of each season, all of the impacts from the SIM-G impact monitor system and ImPACT test scores will be analyzed. The relevant outcome measures to be analyzed include head impact frequency, location, magnitude, symptom scores, memory, visual motor speed and reaction time composite scores. Statistical analysis will be used to determine if the HuTT intervention minimized head impacts and neurocognitive decline compared to the control group.
Minor head injuries are a common presenting complaint in the pediatric emergency department. Skull x-rays are a useful tool in the evaluation of paediatric patients with a history of minor head trauma. However, there exists ongoing controversy regarding the ideal number of views that should be obtained in a skull series. This study aims to determine if there is a significant difference in the diagnostic accuracy of skull x-rays in the diagnosis of fracture in paediatric minor head trauma patients when a 2-film series as opposed to a 4-film series is provided to participating pediatric emergency physicians.
The goal of this study is to evaluate the effect of preventive intravenous infusion of half molar sodium lactate on the onset of hypertensive intracranial episodes in severe head trauma. The investigators hypothesize that preventive intravenous administration of sodium lactate will decrease the number of treatments required to decrease intracranial pressure during 48 hours.
The purpose of this study is to try to prove the worth of the two (2) Serum Proteins S-100 Beta and NSE in combination with a diagnostic algorithm to help to establish diagnosis in patients with minor head injury.