BACKGROUND: Previous work has shown that human amnion-derived progenitor (AMP) cell therapy is neuroprotective in a penetrating ballistic-like brain injury (PBBI) model. However, the neuroprotective capacity of AMP cells seemed to be mediated by the sustained secretion of AMP cell-derived neurotrophic factors, which are abundant in the amnion-derived cellular cytokine suspension (ACCS). To test this theory, the current study assessed the neuroprotective efficacy of long-term ACCS delivery in the PBBI model. METHODS: Experiment 1 assessed the bioactive stability and neuroprotective capacity of ACCS in an in vitro model of neurodegeneration. Experiment 2 evaluated the therapeutic effects of ACCS delivery initiated 15 minutes after PBBI and continued for 2 weeks after injury. Experiment 3 was designed to identify the therapeutic window for long-term ACCS delivery in the PBBI model. Outcome metrics included neurobehavioral assessments and neuropathologic measures of neuroinflammation and axonal/neuronal degeneration. RESULTS: Experiment 1 demonstrated that ACCS is thermally stable for 1 week at 37°C and that ACCS treatment protected neurite against staurosporine toxicity. Experiment 2 identified the optimal infusion rate of ACCS (1 μL/h) and demonstrated that long-term infusion of ACCS was capable of promoting significant protection against PBBI-induced neuropathology and motor abnormalities, but was not sufficient for reducing cognitive deficits. Finally, the results of Experiment 3 showed that ACCS is effective in promoting significant neuroprotection even when onset of treatment is delayed out to 24 hours (but not 48 hours) after PBBI. CONCLUSIONS: Collectively, our results support the hypothesis that the neuroprotective effects of AMP cells are mediated through a sustained delivery of ACCS, which implicates ACCS as a promising neuroprotection agent for clinical study.
BACKGROUND: Previous work has shown that human amnion-derived progenitor (AMP) cell therapy is neuroprotective in a penetrating ballistic-like brain injury (PBBI) model. However, the neuroprotective capacity of AMP cells seemed to be mediated by the sustained secretion of AMP cell-derived neurotrophic factors, which are abundant in the amnion-derived cellular cytokine suspension (ACCS). To test this theory, the current study assessed the neuroprotective efficacy of long-term ACCS delivery in the PBBI model. METHODS: Experiment 1 assessed the bioactive stability and neuroprotective capacity of ACCS in an in vitro model of neurodegeneration. Experiment 2 evaluated the therapeutic effects of ACCS delivery initiated 15 minutes after PBBI and continued for 2 weeks after injury. Experiment 3 was designed to identify the therapeutic window for long-term ACCS delivery in the PBBI model. Outcome metrics included neurobehavioral assessments and neuropathologic measures of neuroinflammation and axonal/neuronal degeneration. RESULTS: Experiment 1 demonstrated that ACCS is thermally stable for 1 week at 37°C and that ACCS treatment protected neurite against staurosporinetoxicity. Experiment 2 identified the optimal infusion rate of ACCS (1 μL/h) and demonstrated that long-term infusion of ACCS was capable of promoting significant protection against PBBI-induced neuropathology and motor abnormalities, but was not sufficient for reducing cognitive deficits. Finally, the results of Experiment 3 showed that ACCS is effective in promoting significant neuroprotection even when onset of treatment is delayed out to 24 hours (but not 48 hours) after PBBI. CONCLUSIONS: Collectively, our results support the hypothesis that the neuroprotective effects of AMP cells are mediated through a sustained delivery of ACCS, which implicates ACCS as a promising neuroprotection agent for clinical study.
Authors: Reas S Khan; Kimberly Dine; Bailey Bauman; Michael Lorentsen; Lisa Lin; Helayna Brown; Leah R Hanson; Aleta L Svitak; Howard Wessel; Larry Brown; Kenneth S Shindler Journal: Sci Rep Date: 2017-01-31 Impact factor: 4.379
Authors: Gabriela A Grinblat; Reas S Khan; Kimberly Dine; Howard Wessel; Larry Brown; Kenneth S Shindler Journal: Invest Ophthalmol Vis Sci Date: 2018-05-01 Impact factor: 4.799
Authors: Bennie H Jeng; Pedram Hamrah; Ziv Z Kirshner; Benjamin C Mendez; Howard C Wessel; Larry R Brown; David L Steed Journal: Transl Vis Sci Technol Date: 2022-01-03 Impact factor: 3.283