RESUMO
Multiple sclerosis is the most common autoimmune disease affecting the central nervous system (CNS) worldwide. Multiple sclerosis involves inflammatory demyelination of nerve fibers in the CNS, often presenting with recurrent episodes of focal sensory or motor deficits associated with the region of the CNS affected. The prevalence of this disease has increased rapidly over the last decade. Despite the approval of many new pharmaceutical therapies in the past 20 years, there remains a growing need for alternative therapies to manage the course of this disease. Treatments are separated into two main categories: management of acute flare versus long-term prevention of flares via disease-modifying therapy. Primary drug therapies for acute flare include corticosteroids to limit inflammation and symptomatic management, depending on symptoms. Several different drugs have been recently approved for use in modifying the course of the disease, including a group of medications known as fumarates (e.g., dimethyl fumarate, diroximel fumarate, monomethyl fumarate) that have been shown to be efficacious and relatively safe. In the present investigation, we review available evidence focused on monomethyl fumarate, also known as Bafiertam®, along with bioequivalent fumarates for the long-term treatment of relapsing-remitting multiple sclerosis.
RESUMO
Often, surgical techniques are practiced and studied in the anatomy laboratory. Occasionally, new surgical methods are developed with cadaveric anatomical studies. Some cadaveric feasibility studies, if published, might go on to be used by surgeons from around the world for improved patient care. Herein, we review our experience with 37 published anatomical feasibility studies over an 18-year period (2002-2020) and analyze the literature for published examples of surgical application of these same anatomical studies. We found that, for cadaveric anatomical feasibility studies within 7 years of their publication date, approximately 22% will be used in neurosurgery with the clinical applications published. Of these studies awarded clinical citation within 7 years of publication, the median time to that citation was approximately 3.4 years. As the average time for translational research to reach patient care is 17 years, cadaveric anatomical studies in this series reached patient care much sooner than traditional translational research. Cadaveric anatomical studies, based on our experience, can drive neurosurgical procedures.