Traumatic brain injury (TBI) causes serious neuronal injury that often leads to death. To date there is no clinically successful treatment strategy that has been reported which offers repair of the brain injury or neural injury. Significant attempts have been made to develop effective therapies for TBI, and one of the most promising approaches is a stem cell based therapeutic approach with mesenchymal stem cells (MSCs). This approach is regarded as having the most potential in regenerative medicine. Toward this venture, the generation and release of exosomes can be attributed to the therapeutic effects of MSCs. Exosomes are nanosized vesicles, carry proteins, lipids, mRNA, and miRNA, and assist in cell−cell communication. Exosomes can interact with brain parenchyma cells and with the neurogenic niche, which can help in neurogenesis and brain remodeling. Exosomes derived from MSCs and human-induced pluripotent stem cells (hiPSCs) can be a promising approach in neuronal injury healing. In this Viewpoint, we discussed the most recent knowledge for exosome therapies for neural injuries and highlighted the major advantages of this therapy.
Chondroitin sulfate proteoglycans (CSPGs) are the most abundant components of glial scar formed after severe traumatic brain injury as well as spinal cord injury and play a crucial inhibitory role in axonal regeneration by selective contraction of filopodia of the growth cone of sprouting neurites. Healing of central nervous system (CNS) injury requires degradation of the glycosamine glycan backbone of CSPGs in order to reduce the inhibitory effect of the CSPG layer. The key focus of this Viewpoint is to address a few important regenerative approaches useful for overcoming the inhibitory barrier caused by chondroitin sulfate proteoglycans.
A fused peptide containing the nuclear localizing sequence (NLS) has been designed and executed, that greatly affects human chronic myelogenous leukemia (CML) cell proliferation by targeting both the nuclear and...
The ingrained mechanical robustness of amyloids in association with their fine-tunable physicochemical properties results in the rational design and synthesis of tailor-made biomaterials for specific applications. However, the incredible antimicrobial efficacy of these ensembles has largely been overlooked. This research work provides an insight into the interplay between selfassembly and antimicrobial activity of amyloid-derived peptide amphiphiles and thereby establishes a newfangled design principle toward the development of potent antimicrobial materials with superior wound healing efficacy. Apart from the relationship with many neurodegenerative diseases, amyloids are now considered as an important cornerstone of our innate immune response against pathogenic microbes. Impelled by this observation, a class of amphiphilic antimicrobial peptide-based biomaterial has been designed by taking Aβ42 as a template. The designed AMP due to its amphipathic nature undergoes rapid self-assembly to form a biocompatible supramolecular hydrogel network having significant antibacterial as well as wound healing effectivity on both Gramnegative P. aeruginosa and MRSA-infected diabetic wounds via reduced inflammatory response and enhanced angiogenesis. Results suggest that disease-forming amyloids can be used as a blueprint for the fabrication of biomaterial-based antimicrobial therapeutics by fine-tuning both the hydrophobicity of the β-aggregation prone zone as well as membrane interacting cationic residues.
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