View clinical trials related to Spinal Cord Neoplasms.
Filter by:This is an open label, Phase 1b safety, dose-finding, brain tumor delivery, and pharmacokinetics study of intranasal NEO100 in patients with pediatric-type diffuse high grade gliomas. Patients will receive IN NEO100 that will follow a dose titration design, followed by a standard dose escalation design to establish safety. Brain tumor delivery of NEO100 will be confirmed in each disease sub-type by surgical resection/needle biopsy only if clinically indicated and scheduled for clinical purposes and testing with residual tissue for NEO100 and the major metabolite of NEO100 (Perillic Acid).
Massive blood loss occurs in metastatic spinal tumor resection and may cause severe complications. The objective of this study is to investigate whether the use of tranexamic acid will reduce perioperative and postoperative bleeding when compared to those without use of tranexamic acid.
Vertebral body resection is a wide accepted procedure in tumor resection, deformity correction, and anterior decompression in spondylosis, ossification of posterior longitudinal ligaments, and spondylodiscitis surgery. However, reconstruction of segmental defect is still challenging to spine surgeon, especially in 3-column resection, such as total en bloc spondylectomy in tumor patients. Various graft or prosthesis for reconstruction has been reported, such as structural allograft, Harms mesh cages, expandable cages, and carbon fiber stackable cages. There are no high evidence level study examining the superiority of those different methods. Recently, 3D printed vertebral body replacement has been reported in different disease entities as well, such as tumor, Kümmell's disease in osteoporosis, and spondylosis. 3D printed implant comes with superiority in production of complex geometries and regularity of the fine surface detailed that promote bone ingrowth. Although, 3D-printed titanium vertebra could achieved bone integration in human, a systemic review showed that the subsidence noted in 31.4% of spine surgery with 3D printed implants. In spine surgery, the fixation construct is sufficiently stiff, interbody motion can be reduced, and loading sharing promotes bone fusion. On the other hand, if the reconstruction is too stiff, stress shielding at fusion site occurs. The concept of dynamic fusion, as opposed to rigid fusion, has been demonstrated by an anterior cervical interbody fusion study in porcine model, demonstrating good bone formation, less postfusion stiffness, and a trend to less subsidence. Thus, we developed a 3D printed, custom-made, biomimetic prosthesis, with non-rigid structure, which has been tested in biomechanical study and porcine model, showing good bone formation and less stiffness as well. Therefore, we proposed a prospective clinical study to investigate safety, subsidence, and fusion of this prosthesis.
This study aims to assess multimodal Radiomics-based prediction model for prognostic prediction in spinal tumors.
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. This can be challenging due to the difficulty of feeling and distinguishing each vertebra, especially for new surgeons, since palpation is a skill derived through experience. 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. The purpose of this study is to test the efficacy and benefits of a new medical device that will aid in radiological localization. The hypothesized outcome would be smaller incisions, faster localization and a reduction in fluoroscopy use. 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 format that is placed against the subject's skin. The grid pattern will then appear on the medical imaging scan. The medical practitioner can correlate device grid on the body to the medical scan image to make their incisions in more accurate locations.
Spinal cord trauma and the consequent paraplegia are possibly among the most devastating injuries in soldiers and during spine surgery, and are significant in the medical, social and financial aspects. Limited mobility, the need for assistance in all human activities, shame, and many medical complications related directly to the neural deficits make paraplegia an important target for prevention. Our study will evaluate the efficacy of Minocycline in two different groups: 1. Minimizing the neurological damage among trauma patients. 2. Preventing neurological damage through operation in spinal tumors patients. 2.OBJECTIVES The primary objectives of the trial are to determine: 1. Efficacy of administrating minocycline in minimizing the neurological damage among acute spinal cord injury patients and spinal cord tumors (primary and metastases) patients? 2. Efficacy of administrating minocycline at changing the natural history and rehabilitation of spinal cord trauma patients. 3. Safety of applying minocycline in spinal cord injuries patients and spinal cord tumors?