Previous studies demonstrate that intrastriatal injections of fibrillar alpha-synuclein (α-syn) into mice induce Parkinson’s disease (PD)-like Lewy body (LB) pathology formed by aggregated α-syn in anatomically interconnected regions and significant nigrostriatal degeneration. The aim of the current study was to evaluate whether exogenous mouse α-syn pre-formed fibrils (PFF) injected into the striatum of rats would result in accumulation of LB-like intracellular inclusions and nigrostriatal degeneration. Sprague Dawley rats received unilateral intrastriatal injections of either non-fibrillized recombinant α-syn or PFF mouse α-syn in 1- or 2- sites and were euthanized at 30, 60 or 180 days post-injection (pi). Both non-fibrillized recombinant α-syn and PFF α-syn injections resulted in phosphorylated α-syn intraneuronal accumulations (i.e., diffuse Lewy neurite (LN)- and LB-like inclusions) with significantly greater accumulations following PFF injection. LB-like inclusions were observed in several areas that innervate the striatum, most prominently the frontal and insular cortices, the amygdala, and the substantia nigra pars compacta (SNpc). α-Syn accumulations co-localized with ubiquitin, p62, and were thioflavin-S-positive and proteinase-k resistant, suggesting PFF-induced pathology exhibits properties similar to human LBs. Although α-syn inclusions within the SNpc remained ipsilateral to striatal injection, we observed bilateral reductions in nigral dopamine neurons at the 180-day time point in both the 1- and 2-site PFF injection paradigms. PFF injected rats exhibited bilateral reductions in striatal dopaminergic innervation at 60 and 180 days and bilateral decreases in homovanillic acid; however, dopamine reduction was observed only in the striatum ipsilateral to PFF injection. Although the level of dopamine asymmetry in PFF injected rats at 180 days was insufficient to elicit motor deficits in amphetamine-induced rotations or forelimb use in the cylinder task, significant disruption of ultrasonic vocalizations was observed. Taken together, our findings demonstrate that α-syn PFF are sufficient to seed the pathological conversion and propagation of endogenous α-syn to induce a progressive, neurodegenerative model of α-synucleinopathy in rats.
Wound care is one of the leading health care problems in the United States costing billions of dollars yearly. Annually, millions of acute wounds occur due to surgical procedures or traumas such as burns and abrasions, and these wounds can become non-healing due to bacterial infection or underlying pathologies. Current wound care treatments include the use of bioinert constructs combined with topical administration of anti-bacterial agents and growth factors. However, there is a growing need for the development of bioactive wound dressing materials that are able to promote wound healing and the regeneration of healthy tissue. In this work, we evaluate and report the use of a novel electrospun polymeric scaffold consisting of poly (1,8 octanediol-co-citrate) and poly (acrylic acid) for wound healing applications. The scaffold exhibits intrinsic antibacterial activity, hydrogel-like water uptake abilities, and the ability to deliver physiologically relevant concentrations of growth factor. Additionally, the scaffold shows antibacterial function when tested with bacteria relevant to wound healing applications. Biological characterization of the electrospun scaffold shows excellent cellular adhesion, low cytotoxicity, and enhanced proliferation of skin fibroblasts. This work has potential towards the development of novel bioactive scaffolds for prevention of bacterial infiltration into the wound bed and enhanced healing.
The negative effects of space flight on cardiovascular health of astronauts have been demonstrated and documented over many years. Endothelial cells (ECs) play an important role in regulating weightlessness-induced cardiovascular dysfunction. This project seeks to study the effect of microgravity on the differentiation of endothelial progenitor cells (EPCs) into ECs and the downstream functions of the differentiated cells. Initial exposure of EPCs to microgravity indicated an inhibition of migratory, proliferative, and antithrombogenic capacity of the differentiated ECs. However, our results indicate a potential recovery of proliferative and antithrombogenic functions on prolonged exposure to microgravity.
Biodegradable Mg alloys have the potential to replace currently used metallic medical implant devices, likely eliminating toxicity concerns and the need for secondary surgeries, while also providing a potentially stimulating environment for tissue growth. A recently developed Mg–Ca–Sr alloy possesses advantageous characteristics over other Mg alloys, having a good combination of strength and degradation behavior, while also displaying potentially osteogenic properties. To better understand the effect of alloy degradation products on cellular mechanisms, in vitro studies using human bone marrow‐derived mesenchymal stem cells were conducted. Ionic products of alloy dissolution were found to be nontoxic but changed the proliferation profile of stem cells. Furthermore, their presence changed the progress of osteogenic development, while concentrations of Mg in particular appeared to induce stem cell differentiation. The work presented herein provides a foundation for future alloy design where structures can be tailored to obtain specific implant performance. These potentially bioactive implants would reduce the risks for patients by shortening their healing time, minimizing discomfort and toxicity concerns, while reducing hospital costs. © 2017 The Authors Journal of Biomedical Materials Research Part B: Applied Biomaterials Published by Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 106B: 697–704, 2018.
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