Spinal cord injury (SCI) is a serious trauma, which often results in a permanent loss of motor and sensory functions, pain and spasticity. Despite extensive research, there is currently no available therapy that would restore the lost functions after SCI in human patients. Advanced treatments use regenerative medicine or its combination with various interdisciplinary approaches such as tissue engineering or biophysical methods. This review summarizes and critically discusses the research from specific interdisciplinary fields in SCI treatment such as the development of biomaterials as scaffolds for tissue repair, and using a magnetic field for targeted cell delivery. We compare the treatment effects of synthetic non-degradable methacrylate-based hydrogels and biodegradable biological scaffolds based on extracellular matrix. The systems using magnetic fields for magnetically guided delivery of stem cells loaded with magnetic nanoparticles into the lesion site are then suggested and discussed.

• Keywords
• Biomaterials, Cell delivery, Hydrogel, Magnetic field, Spinal cord injury,
• MeSH
• Biocompatible Materials pharmacology   therapeutic use   MeSH
• Hydrogels therapeutic use   MeSH
• Humans MeSH
• Magnetic Field Therapy methods   trends   MeSH
• Spinal Cord Injuries physiopathology   therapy   MeSH
• Nerve Regeneration drug effects   physiology   MeSH
• Stem Cell Transplantation methods   trends   MeSH
• Animals MeSH
• Check Tag
• Humans MeSH
• Animals MeSH
• Publication type
• Journal Article MeSH
• Review MeSH
• Names of Substances
• Biocompatible Materials MeSH
• Hydrogels MeSH

Manganese-zinc ferrite nanoparticles were synthesized by using a hydrothermal treatment, coated with silica, and then tested as efficient cellular labels for cell tracking, using magnetic resonance imaging (MRI) in vivo. A toxicity study was performed on rat mesenchymal stem cells and C6 glioblastoma cells. Adverse effects on viability and cell proliferation were observed at the highest concentration (0.55 mM) only; cell viability was not compromised at lower concentrations. Nanoparticle internalization was confirmed by transmission electron microscopy. The particles were found in membranous vesicles inside the cytoplasm. Although the metal content (0.42 pg Fe/cell) was lower compared to commercially available iron oxide nanoparticles, labeled cells reached a comparable relaxation rate R 2, owing to higher nanoparticle relaxivity. Cells from transgenic luciferase-positive rats were used for in vivo experiments. Labeled cells were transplanted into the muscles of non-bioluminescent rats and visualized by MRI. The cells produced a distinct hypointense signal in T2- or T2*-weighted MR images in vivo. Cell viability in vivo was verified by bioluminescence.

• Keywords
• cell labeling, cell transplantation, doping, magnetic resonance imaging, nanoparticles,
• Publication type
• Journal Article MeSH