-
International Journal of Surgery Case... Aug 2023Spinal tumors constitute 15 % of all tumors in the central nervous system. Pain is often the initial symptom, which can be localized, nocturnal, or radiated to the arms...
INTRODUCTION
Spinal tumors constitute 15 % of all tumors in the central nervous system. Pain is often the initial symptom, which can be localized, nocturnal, or radiated to the arms and/or limbs. We report a rare case with a subpial lipoma in the cervicothoracic spine and review the current literature.
CASE PRESENTATION
A 22-year-old female presented with the chief complaint of tetraparesis for three months before admission. Magnetic resonance imaging revealed an intradural tumor on the fifth cervical to fourth thoracic vertebrae. She underwent a laminectomy to remove the tumor completely. Histopathological examination revealed a proliferation of mature fat cells amongst fibrous connective tissue. Surrounding nerve fibers and erythrocyte-filled blood vessels were also found, suggesting a subpial fibrolipoma. Postoperatively, there was an improvement in muscle strength six weeks after surgery. Motoric strength was grade 5 for the upper extremities and grade 4 for the lower extremities.
DISCUSSION
In this patient, cervicothoracic laminectomy and tumor removal were performed without instrumentation. Total tumor resection is the primary goal when removing a pathological lesion. However, this depends on the lesion's adhesion to the surrounding tissue. Therefore, partial tumor resection may be possible, given the neurological complications that can occur.
CONCLUSION
Because subpial lipomas are rare, their treatment is highly specialized. An assessment of the patient's physical condition and imaging assessments can provide information about potential treatment strategies and outcomes.
PubMed: 37544094
DOI: 10.1016/j.ijscr.2023.108616 -
ACS Applied Bio Materials Aug 2023Natural polymers from organic wastes have gained increasing attention in the biomedical field as resourceful second raw materials for the design of biomedical devices...
Natural polymers from organic wastes have gained increasing attention in the biomedical field as resourceful second raw materials for the design of biomedical devices which can perform a specific bioactive function and eventually degrade without liberating toxic residues in the surroundings. In this context, patches and bandages, that need to support the skin wound healing process for a short amount of time to be then discarded, certainly constitute good candidates in our quest for a more environmentally friendly management. Here, we propose a plant-based microfibrous scaffold, loaded with vitamin C (VitC), a bioactive molecule which acts as a protecting agent against UV damages and as a wound healing promoter. Fibers were fabricated via electrospinning from various zein/pectin formulations, and subsequently cross-linked in the presence of Ca to confer them a hydrogel-like behavior, which we exploited to tune both the drug release profile and the scaffold degradation. A comprehensive characterization of the physico-chemical properties of the zein/pectin/VitC scaffolds, either pristine or cross-linked, has been carried out, together with the bioactivity assessment with two representative skin cell populations (human dermal fibroblast cells and skin keratinocytes, HaCaT cells). Interestingly, col-1a gene expression of dermal fibroblasts increased after 3 days of growth in the presence of the microfiber extraction media, indicating that the released VitC was able to stimulate collagen mRNA production overtime. Antioxidant activity was analyzed on HaCaT cells via DCFH-DA assay, highlighting a fluorescence intensity decrease proportional to the amount of loaded VitC (down to 50 and 30%), confirming the protective effect of the matrices against oxidative stress. Finally, the most performing samples were selected for the in vivo test on a skin UVB-burn mouse model, where our constructs demonstrated to significantly reduce the inflammatory cytokines expression in the injured area (50% lower than the control), thus constituting a promising, environmentally sustainable alternative to skin patches.
Topics: Animals; Humans; Male; Mice; Antioxidants; Ascorbic Acid; Biocompatible Materials; Burns; Cell Line; Hydrogels; Keratinocytes; Mice, Inbred C57BL; Wound Healing; Zein; Zea mays
PubMed: 37493659
DOI: 10.1021/acsabm.3c00214