Your search keyword '"Martirosian, Vahan"' showing total 4 results

1. Stem Cell Transplantation Reverses Chemotherapy-Induced Cognitive Dysfunction.

Author

Acharya, Munjal M., Martirosian, Vahan, Chmielewski, Nicole N., Hanna, Nevine, Tran, Katherine K., Liao, Alicia C., Christie, Lori-Ann, Parihar, Vipan K., and Limoli, Charles L.

Subjects

*CANCER chemotherapy, *COGNITION disorders research, *HIPPOCAMPUS (Brain), *STEM cell transplantation research, *CYCLOPHOSPHAMIDE

Abstract

The frequent use of chemotherapy to combat a range of malignancies can elicit severe cognitive dysfunction often referred to as "chemobrain," a condition that can persist long after the cessation of treatment in as many as 75% of survivors. Although cognitive health is a critical determinant of therapeutic outcome, chemobrain remains an unmet medical need that adversely affects quality of life in pediatric and adult cancer survivors. Using a rodent model of chemobrain, we showed that chronic cyclophosphamide treatment induced significant performance-based decrements on behavioral tasks designed to interrogate hippocampal and cortical function. Intrahippocampal transplantation of human neural stem cells resolved all cognitive impairments when animals were tested 1 month after the cessation of chemotherapy. In transplanted animals, grafted cells survived (8%) and differentiated along neuronal and astroglial lineages, where improved cognition was associated with reduced neuroinflammation and enhanced host dendritic arborization. Stem cell transplantation significantly reduced the number of activated microglia after cyclophosphamide treatment in the brain. Granule and pyramidal cell neurons within the dentate gyrus and CA1 subfields of the hippocampus exhibited significant reductions in dendritic complexity, spine density, and immature and mature spine types following chemotherapy, adverse effects that were eradicated by stem cell transplantation. Our findings provide the first evidence that cranial transplantation of stem cells can reverse the deleterious effects of chemobrain, through a trophic support mechanism involving the attenuation of neuroinflammation and the preservation host neuronal architecture. [ABSTRACT FROM AUTHOR]

Published

2015

2. Long-term cognitive effects of human stem cell transplantation in the irradiated brain.

Author

Acharya, Munjal M., Martirosian, Vahan, Christie, Lori-Ann, and Limoli, Charles L.

Subjects

*STEM cell transplantation, *BRAIN tumor treatment, *RADIOTHERAPY complications, *COGNITION disorders treatment, *RADIATION-induced abnormalities, *THERAPEUTICS

Abstract

Purpose: Radiotherapy remains a primary treatment modality for the majority of central nervous system tumors, but frequently leads to debilitating cognitive dysfunction. Given the absence of satisfactory solutions to this serious problem, we have used human stem cell therapies to ameliorate radiation-induced cognitive impairment. Here, past studies have been extended to determine whether engrafted cells provide even longer-term benefits to cognition. Materials and methods: Athymic nude rats were cranially irradiated (10 Gy) and subjected to intrahippocampal transplantation surgery 2 days later. Human embryonic stem cells (hESC) or human neural stem cells (hNSC) were transplanted, and animals were subjected to cognitive testing on a novel place recognition task 8 months later. Results: Grafting of hNSC was found to provide long lasting cognitive benefits over an 8-month post-irradiation interval. At this protracted time, hNSC grafting improved behavioral performance on a novel place recognition task compared to irradiated animals not receiving stem cells. Engrafted hESC previously shown to be beneficial following a similar task, 1 and 4 months after irradiation, were not found to provide cognitive benefits at 8 months. Conclusions: Our findings suggest that hNSC transplantation promotes the long-term recovery of the irradiated brain, where intrahippocampal stem cell grafting helps to preserve cognitive function. [ABSTRACT FROM AUTHOR]

Published

2014

3. Cranial grafting of stem cell-derived microvesicles improves cognition and reduces neuropathology in the irradiated brain.

Author

Baulch, Janet E., Acharya, Munjal M., Allen, Barrett D., Ning Ru, Chmielewski, Nicole N., Martirosian, Vahan, Giedzinski, Erich, Syage, Amber, Park, Audrey L., Benke, Sarah N., Parihar, Vipan K., and Limoli, Charles L.

Subjects

*CRANIAL nerves, *NEUROLOGICAL disorders, *COGNITION, *NEURAL stem cells, *HIPPOCAMPUS (Brain)

Abstract

Cancer survivors face a variety of challenges as they cope with disease recurrence and a myriad of normal tissue complications brought on by radio- and chemotherapeutic treatment regimens. For patients subjected to cranial irradiation for the control of CNS malignancy, progressive and debilitating cognitive dysfunction remains a pressing unmet medical need. Although this problem has been recognized for decades, few if any satisfactory long-term solutions exist to resolve this serious unintended side effect of radiotherapy. Past work from our laboratory has demonstrated the neurocognitive benefits of human neural stem cell (hNSC) grafting in the irradiated brain, where intrahippocampal transplantation of hNSC ameliorated radiation-induced cognitive deficits. Using a similar strategy, we now provide, to our knowledge, the first evidence that cranial grafting of microvesicles secreted from hNSC affords similar neuroprotective phenotypes after headonly irradiation. Cortical- and hippocampal-based deficits found 1 mo after irradiation were completely resolved in animals cranially grafted with microvesicles. Microvesicle treatment was found to attenuate neuroinflammation and preserve host neuronal morphology in distinct regions of the brain. These data suggest that the neuroprotective properties of microvesicles act through a trophic support mechanism that reduces inflammation and preserves the structural integrity of the irradiated microenvironment. [ABSTRACT FROM AUTHOR]

Published

2016

4. Targeted Overexpression of Mitochondrial Catalase Prevents Radiation-Induced Cognitive Dysfunction.

Author

Parihar, Vipan K., Allen, Barrett D., Tran, Katherine K., Chmielewski, Nicole N., Craver, Brianna M., Martirosian, Vahan, Morganti, Josh M., Rosi, Susanna, Vlkolinsky, Roman, Acharya, Munjal M., Nelson, Gregory A., Allen, Antiño R., and Limoli, Charles L.

Subjects

*GENETIC overexpression, *OXIDATIVE stress, *LABORATORY mice, *RADIATION, *MORPHOLOGY, *OXIDATION-reduction reaction

Abstract

Aims: Radiation-induced disruption of mitochondrial function can elevate oxidative stress and contribute to the metabolic perturbations believed to compromise the functionality of the central nervous system. To clarify the role of mitochondrial oxidative stress in mediating the adverse effects of radiation in the brain, we analyzed transgenic (mitochondrial catalase [MCAT]) mice that overexpress human catalase localized to the mitochondria. Results: Compared with wild-type (WT) controls, overexpression of the MCAT transgene significantly decreased cognitive dysfunction after proton irradiation. Significant improvements in behavioral performance found on novel object recognition and object recognition in place tasks were associated with a preservation of neuronal morphology. While the architecture of hippocampal CA1 neurons was significantly compromised in irradiated WT mice, the same neurons in MCAT mice did not exhibit extensive and significant radiation-induced reductions in dendritic complexity. Irradiated neurons from MCAT mice maintained dendritic branching and length compared with WT mice. Protected neuronal morphology in irradiated MCAT mice was also associated with a stabilization of radiation-induced variations in long-term potentiation. Stabilized synaptic activity in MCAT mice coincided with an altered composition of the synaptic AMPA receptor subunits GluR1/2. Innovation: Our findings provide the first evidence that neurocognitive sequelae associated with radiation exposure can be reduced by overexpression of MCAT, operating through a mechanism involving the preservation of neuronal morphology. Conclusion: Our article documents the neuroprotective properties of reducing mitochondrial reactive oxygen species through the targeted overexpression of catalase and how this ameliorates the adverse effects of proton irradiation in the brain. Antioxid. Redox Signal. 22, 78-91. [ABSTRACT FROM AUTHOR]

Published

2015