Miranda M. Brenneman scite author profile

Stroke is a common cause of permanent disability accompanied by devastating impairments for which there is a pressing need for effective treatment. Motor, sensory and cognitive deficits are common following stroke, yet treatment is limited. Along with histological measures, functional outcome in animal models has provided valuable insight to the biological basis and potential rehabilitation efforts of experimental stroke. Developing and using tests that have the ability to identify behavioral deficits is essential to expanding the development of translational therapies. The present aim of this paper is to review many of the current behavioral tests that assess functional outcome after stoke in rodent models. While there is no perfect test, there are many assessments that are sensitive to detecting the array of impairments, from global to modality specific, after stroke.

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Autologous Bone Marrow Mononuclear Cells Enhance Recovery after Acute Ischemic Stroke in Young and Middle-Aged Rats

Brenneman¹,

Sharma²,

Harting³

et al. 2009

J Cereb Blood Flow Metab

188

197

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We investigated intra-arterially administered autologous bone marrow mononuclear cells (MNCs) in rats with acute ischemic stroke. Long Evans rats (2 to 3 months or 12 months old) underwent tandem reversible common carotid artery (CCA)/middle cerebral artery (MCA) occlusion (CCAo/MCAo) for 3 h and then 24 h later underwent tibial bone marrow harvest. Ten million or 4 million cells were re-injected by an intra-carotid infusion. Control animals underwent marrow needle insertion and then saline injection into the carotid artery. Animals were assessed on a battery of neurological tests. MNCs in the ischemic brain were tracked using Q-dot nanocrystal labeling. Infarct volume and cytokines in the ischemia-affected brain were analyzed. Cell-treated animals in the younger and older groups showed improvement from 7 to 30 days after stroke compared with vehicle-treated animals. MNCs significantly reduced infarct volume compared with saline. There was a significant reduction in tumor necrosis factor-α, interleukin-1α (IL-1α), IL-β, IL-6, and a significant increase in IL-10 in injured brains harvested from the cell-treated groups compared with saline controls. Labeled MNCs were found in the peri-infarcted area at 1 h and exponentially decreased over the ensuing week after injection. Autologous bone marrow MNCs can be safely harvested from rodents after stroke, migrate to the peri-infarct area, enhance recovery, and modulate the post-ischemic inflammatory response.

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Delayed Treatment with Monoclonal Antibody IN-1 1 Week after Stroke Results in Recovery of Function and Corticorubral Plasticity in Adult Rats

Seymour

Andrews

Tsai

et al. 2005

J Cereb Blood Flow Metab

121

103

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Neuronal death due to ischemic stroke results in permanent deficits in sensory, language, and motor functions. The growth-restrictive environment of the adult central nervous system (CNS) is an obstacle to functional recovery after stroke and other CNS injuries. In this regard, Nogo-A is a potent neurite growth-inhibitory protein known to restrict neuronal plasticity in adults. Previously, we have found that treatment with monoclonal antibody (mAb) IN-1 to neutralize Nogo-A immediately after stroke enhanced motor cortico-efferent plasticity and recovery of skilled forelimb function in rats. However, immediate treatment for stroke is often not clinically feasible. Thus, the present study was undertaken to determine whether cortico-efferent plasticity and functional recovery would occur if treatment with mAb IN-1 was delayed 1 week after stroke. Adult rats were trained on a forelimb-reaching task, and the middle cerebral artery was occluded to induce focal cerebral ischemia to the forelimb sensorimotor cortex. After 1 week, animals received mAb IN-1 treatment, control antibody, or no treatment, and were tested for 9 more weeks. To assess cortico-efferent plasticity, the sensorimotor cortex opposite the stroke lesion was injected with an anterograde neuroanatomical tracer. Behavioral analysis demonstrated a recovery of skilled forelimb function, and anatomical studies revealed neuroplasticity at the level of the red nucleus in animals treated with mAb IN-1, thus demonstrating the efficacy of this treatment even if administered 1 week after stroke.

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Therapeutic time window and dose response of autologous bone marrow mononuclear cells for ischemic stroke

Yang¹,

Strong²,

Sharma³

et al. 2011

J. Neurosci. Res.

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Although mononuclear cells (MNCs) from bone marrow are being investigated in phase I clinical trials in stroke patients, dose response, therapeutic time window and biodistribiton have not been well-characterized in animal stroke models. Long Evans rats underwent common carotid artery/middle cerebral artery occlusion (CCA/MCAo) and 24 hrs later were randomized to receive saline IV or a bone marrow aspiration followed by an IV infusion of autologous separated MNCs (1 million, 10 million or 30 million cells/kg). In another experiment, rats underwent CCAo/MCAo and were randomized at 24 hrs, 72 hrs or 7 days after stroke to receive a saline injection or 10 million/kg MNCs. All animals were evaluated on the cylinder and corner tests up to 28 days. MNCs were tracked using Q-dot nanocrystals to monitor biodistribution. Animals treated with MNCs at 10 million and 30 million cells/kg at 24 hrs after stroke had significant reductions in neurological deficits and lesion size compared to saline controls or animals treated with 1 million cells/kg. There was no difference in neurological deficits in the 10 and 30 million cell/kg groups at 28 days. Animals treated with MNCs at 72 hrs but not at 7 days showed a significant reduction in neurological deficits by 28 days. Labeled MNCs were found in the brain, spleen, lung, liver, and kidney at 1 hr and exponentially decreased over the ensuing week. In conclusion, we found a maximum reduction in neurological deficits at 10 and 30 million cells/kg and a therapeutic time window up to 72 hrs after stroke.

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Bone marrow mononuclear cells protect neurons and modulate microglia in cell culture models of ischemic stroke

Sharma¹,

Yang²,

Strong³

et al. 2010

J of Neuroscience Research

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Background Although several studies have provided evidence for the therapeutic potential of bone marrow-derived mononuclear cells (MNCs) in animal models of stroke, the mechanisms underlying their benefits remain largely unknown. We have determined the neuroprotective potential of MNCs in primary neuronal cultures exposed to various injuries in vitro. Methods Cortical neurons in culture were exposed to oxygen-glucose deprivation, hypoxia, or hydrogen peroxide and cell death was assayed by MTT, caspase-3 activation or TUNEL labelling at 24 hrs. Cultures were randomized to co-treatment with MNC-derived supernatants or media before injury exposure. In separate experiments, macrophage or microglial cultures were exposed to lipopolypolysacharide (LPS) in the presence and absence of MNC-derived supernatants. Neuronal cultures were then exposed to conditioned media derived from activated macrophages or microglia. Cytokines from the supernantants of MNC cultures exposed to normoxia or hypoxia were also estimated by enzyme-linked immunosorbant assay (ELISA). Results MNC-derived supernatants attenuated neuronal death induced by OGD, hypoxia, hydrogen peroxide, and conditioned macrophage/microglial media and contain a number of trophic factors including IL-10, IGF-1, VEGF, and SDF-1. Conclusion MNCs provide broad neuroprotection against a variety of injuries relevant to stroke.

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