Deborah A. Shear

Biocompatibility of methylcellulose-based constructs designed for intracerebral gelation following experimental traumatic brain injury

Tissue engineering in the post-injury brain represents a promising option for cellular replacement and rescue, providing a cell scaffold for either transplanted or resident cells. We have characterized the use of methylcellulose (MC) as a scaffolding material, whose concentration and solvent were varied to manipulate its physical properties. MC solutions were produced to exhibit low viscosity at 23 degrees C and form a soft gel at 37 degrees C, thereby making MC attractive for minimally invasive procedures in vivo. Degradation and swelling studies in vitro demonstrated a small amount of initial polymer erosion followed by relative polymer stability over the 2-week period tested as well as increased hydrogel mass due to solvent uptake. Concentrations up to 8% did not elicit cell death in primary rat astrocytes or neurons at 1 or 7 days. Acellular 2% MC (30 microl) was microinjected into the brains of rats 1 week after cortical impact injury (velocity = 3 m/s, depth = 2 mm) and examined at 2 days (n = 8; n = 3, vehicle injected) and 2 weeks (n = 5; n = 3, vehicle injected). The presence of MC did not alter the size of the injury cavity or change the patterns of gliosis as compared to injured, vehicle-injected rats (detected using antibodies against GFAP and ED1). Collectively, these data indicate that MC is well suited as a biocompatible injectable scaffold for the repair of defects in the brain.

Progesterone protects against necrotic damage and behavioral abnormalities caused by traumatic brain injury.

A single injection of progesterone can attenuate cerebral edema when administered during the first 24 h after traumatic brain injury (TBI) in rats but this regimen may not always produce functional benefits. In this experiment, we sought to find the duration of progesterone administration needed to facilitate both behavioral and morphological recovery. Male rats received bilateral contusions of the medial prefrontal cortex and were given progesterone (4 mg/kg) or vehicle for 3 or 5 days postoperatively. Both the 3- and the 5-day progesterone regimens reduced the size of injury- induced necrosis and cell loss, with the 5-day schedule being most effective. With regard to behavioral outcome, only 5 days of progesterone injections resulted in improved spatial learning performance and reduced sensory neglect. These results show that 5 days of postinjury progesterone treatment are needed to reduce significantly the neuropathological and behavioral abnormalities found in a rodent model of TBI. These benefits of progesterone, in the absence of any known side effects, provide further support for clinical testing of this neurosteroid.

Neural progenitor cell transplants promote long-term functional recovery after traumatic brain injury

Studies demonstrating the versatility of neural progenitor cells (NPCs) have recently rekindled interest in neurotransplantation methods aimed at treating traumatic brain injury (TBI). However, few studies have evaluated the safety and functional efficacy of transplanted NPCs beyond a few months. The purpose of this study was to assess the long-term survival, migration, differentiation and functional significance of NPCs transplanted into a mouse model of TBI out to 1 year post-transplant. NPCs were derived from E14.5 mouse brains containing a transgene-expressing green fluorescent protein (GFP) and cultured as neurospheres in FGF2-containing medium. Neurospheres were injected into the ipsilateral striatum of adult C57BL/6 mice 1 week following unilateral cortical impact injury. Behavioral testing revealed significant improvements in motor abilities in NPC-treated mice as early as 1 week, and the recovery was sustained out to 1 year post-transplant. In addition, mice receiving NPC transplants showed significant improvement in spatial learning abilities at 3 months and 1 year, whereas an intermediate treatment effect on this behavioral parameter was detected at 1 month. At 14 months post-transplant, GFP(+) NPCs were observed throughout the injured hippocampus and adjacent cortical regions of transplanted brains. Immunohistochemical analysis revealed that the majority of transplanted cells co-labeled for NG2, an oligodendrocyte progenitor cell marker, but not for neuronal, astrocytic or microglial markers. In conclusion, transplanted NPCs survive in the host brain up to 14 months, migrate to the site of injury, enhance motor and cognitive recovery, and may play a role in trophic support following TBI.

Laminin and fibronectin scaffolds enhance neural stem cell transplantation into the injured brain

Cell transplantation offers the potential to treat central nervous system injuries, largely because multiple mechanisms can be targeted in a sustained fashion. It is crucial that cells are transplanted into an environment that is favourable for extended survival and integration within the host tissue. Given the success of using fetal tissue grafts for traumatic brain injury, it may be beneficial to mimic key aspects of these grafts (e.g. three‐dimensionality, cell–cell and cell–matrix support) to deliver cells. Extracellular matrix proteins such as fibronectin and laminin are involved in neural development and may provide adhesive support for donor cells and mediate subsequent cell signalling events. In this study, neural stem cells were transplanted into the traumatically injured mouse brain within a tissue‐engineered construct containing either a laminin‐ or fibronectin‐based scaffold. Cells delivered within the scaffolds were more widely distributed in the injured brain compared to cells delivered in media alone. There were no differences in donor cell survival at 1 week post‐transplant; however, by 8 weeks post‐transplant, cells delivered within the scaffolds showed improved survival compared to those transplanted in media alone. Survival was more enhanced with the laminin‐based scaffold compared to the fibronectin‐based scaffold. Furthermore, behavioural analyses indicated that mice receiving neural stem cells within the laminin‐based scaffold performed significantly better than untreated mice on a spatial learning task, supporting the notion that functional recovery correlates positively with donor cell survival. Together these results suggest that the use of appropriate extracellular matrix‐based scaffolds can be exploited to improve cell transplantation therapy. Copyright

Fibronectin promotes survival and migration of primary neural stem cells transplanted into the traumatically injured mouse brain

Multipotential stem cells are an attractive choice for cell therapy after traumatic brain injury (TBI), as replacement of multiple cell types may be required for functional recovery. In the present study, neural stem cells (NSCs) derived from the germinal zone of E14.5 GFP-expressing mouse brains were cultured as neurospheres in FGF2-enhanced medium. When FGF2 was removed in vitro, NSCs expressed phenotypic markers for neurons, astrocytes, and oligodendrocytes and exhibited migratory behavior in the presence of adsorbed fibronectin (FN). NSCs (105 cells) were transplanted into mouse brains 1 week after a unilateral, controlled, cortical contusion (depth = 1 mm, velocity = 6 m/s, duration = 150 ms) (n = 19). NSCs were injected either directly into the injury cavity with or without an injectable FN-based scaffold [collagen I (CnI)/ FN gel; n = 14] or into the striatum below the injury cavity (n = 5). At all time points examined (1 week to 3 months posttransplant), GFP+ cells were confined to the ipsilateral host brain tissue. At 1 week, cells injected into the injury cavity lined the injury penumbra while cells inserted directly into the striatum remained in or around the needle track. Striatal transplants had a lower number of surviving GFP+ cells relative to cavity injections at the 1 week time point (p < 0.01). At the longer survival times (3 weeks–3 months), 63–76% of transplanted cells migrated into the fimbria hippocampus regardless of injection site, perhaps due to cues from the degenerating hippocampus. Furthermore, cells injected into the cavity within a FN-containing matrix showed increased survival and migration at 3 weeks (p < 0.05 for both) relative to injections of cells alone. These results suggest that FGF2-responsive NSCs present a promising approach for cellular therapy following trauma and that the transplant location and environment may play an important role in graft survival and integration.

Creatine reduces 3-nitropropionic-acid-induced cognitive and motor abnormalities in rats.

This study assessed whether creatine could attenuate 3-nitropropionic acid (3NP)-induced neuropathological and behavioral abnormalities that are analogous to those observed in Huntingtons disease (HD). Rats were fed diets containing either 1% creatine or normal rat chow for 2 weeks prior to the onset of 3NP administration, and for the duration of the study. 3NP was administered systemically in gradually increasing concentrations over an 8-week testing period. Results show that creatine can attenuate 3NP-induced striatal lesions, striatal atrophy, ventricular enlargement, cognitive deficits, and motor abnormalities on a balance beam task. Collectively, these findings indicate that creatine provides significant protection against 3NP-induced behavioral and neuropathological abnormalities and may have therapeutic potential for HD.

Stem cell survival and functional outcome after traumatic brain injury is dependent on transplant timing and location

PURPOSEnRecent work indicates that transplanted neural stem cells (NSCs) can survive, migrate to the injury site, and facilitate recovery from traumatic brain injury (TBI). The present study manipulated timing and location of NSC transplants following controlled cortical impact injury (CCI) in mice to determine optimal transplant conditions.nnnMETHODSnIn Experiment 1 (timing), NSCs (E14.5 mouse) were injected into the host striatum, ipsilateral to the injury, at 2, 7, or 14 days. In Experiment 2 (location), NSCs or vehicle were injected into the mouse striatum (7 days post-CCI) either ipsilateral or contralateral to the injury and cognitive and motor abilities were assessed from weeks 1-8 post-transplant. Histological measures of NSC survival, migration, and differentiation were taken at 6 and 8 weeks post-transplant.nnnRESULTSnThe results demonstrate that: (1) 2-7 days post-injury is the optimal time-range for delivering NSCs; (2) time of transplantation does not affect short-term phenotypic differentiation; (3) transplant location affects survival, migration, phenotype, and functional efficacy; and (4) NSC-mediated functional recovery is not contingent upon NSC migration or phenotypic differentiation.nnnCONCLUSIONSnThese findings provide further support for the idea that mechanisms other than the replacement of damaged neurons or glia, such as NSC-induced increases in protective neurotrophic factors, may be responsible for the functional recovery observed in this model of TBI.

Subacute Changes in Cleavage Processing of Amyloid Precursor Protein and Tau following Penetrating Traumatic Brain Injury.

Traumatic brain injury (TBI) is an established risk factor for the development of Alzheimer’s disease (AD). Here the effects of severe penetrating TBI on APP and tau cleavage processing were investigated in a rodent model of penetrating ballistic-like brain injury (PBBI). PBBI was induced by stereotactically inserting a perforated steel probe through the right frontal cortex of the anesthetized rat and rapidly inflating/deflating the probe’s elastic tubing into an elliptical shaped balloon to 10% of total rat brain volume causing temporary cavitation injury. Separate animals underwent probe injury (PrI) alone without balloon inflation. Shams underwent craniectomy. Brain tissue was collected acutely (4h, 24h, 3d) and subacutely (7d) post-injury and analyzed by immunoblot for full length APP (APP-FL) and APP beta c-terminal fragments (βCTFs), full length tau (tau-FL) and tau truncation fragments and at 7d for cytotoxic Beta amyloid (Aβ) peptides Aβ40 and Aβ42 analysis. APP-FL was significantly decreased at 3d and 7d following PBBI whereas APP βCTFs were significantly elevated by 4h post-injury and remained elevated through 7d post-injury. Effects on βCTFs were mirrored with PrI, albeit to a lesser extent. Aβ40 and Aβ42 were significantly elevated at 7d following PBBI and PrI. Tau-FL decreased substantially 3d and 7d post-PBBI and PrI. Importantly, a 22 kDa tau fragment (tau22), similar to that found in AD, was significantly elevated by 4h and remained elevated through 7d post-injury. Thus both APP and tau cleavage was dramatically altered in the acute and subacute periods post-injury. As cleavage of these proteins has also been implicated in AD, TBI pathology shown here may set the stage for the later development of AD or other tauopathies.

Treatment with amnion-derived cellular cytokine solution (ACCS) induces persistent motor improvement and ameliorates neuroinflammation in a rat model of penetrating ballistic-like brain injury

PURPOSEnThe present work compared the behavioral outcomes of ACCS therapy delivered either intravenously (i.v.) or intracerebroventricularly (i.c.v.) after penetrating ballistic-like brain injury (PBBI). Histological markers for neuroinflammation and neurodegeneration were employed to investigate the potential therapeutic mechanism of ACCS.nnnMETHODSnExperiment-1, ACCS was administered either i.v. or i.c.v. for 1 week post-PBBI. Outcome metrics included behavioral (rotarod and Morris water maze) and gross morphological assessments. Experiment-2, rats received ACCS i.c.v for either 1 or 2 weeks post-PBBI. The inflammatory response was determined by immunohistochemistry for neutrophils and microglia reactivity. Neurodegeneration was visualized using silver staining.nnnRESULTSnBoth i.v. and i.c.v. delivery of ACCS improved motor outcome but failed to improve cognitive outcome or tissue sparing. Importantly, only i.c.v. ACCS treatment produced persistent motor improvements at a later endpoint. The i.c.v. ACCS treatment significantly reduced PBBI-induced increase in myeloperoxidase (MPO) and ionized calcium binding adaptor molecule 1 (Iba1) expression. Concomitant reduction of both Iba1 and silver staining were detected in corpus callosum with i.c.v. ACCS treatment.nnnCONCLUSIONSnACCS, as a treatment for TBI, showed promise with regard to functional (motor) recovery and demonstrated strong capability to modulate neuroinflammatory responses that may underline functional recovery. However, the majority of beneficial effects appear restricted to the i.c.v. route of ACCS delivery, which warrants future studies examining delivery routes (e.g. intranasal delivery) which are more clinically viable for the treatment of TBI.

Cognitive and Motor Deficits Produced by Acute and Chronic Administration of 3-Nitropropionic Acid in Rats

The mitochondrial toxin 3-nitropropionic acid (3-NPA) has received substantial attention recently as a potential tool for studying the types of neuro-pathological and behavioral deficits observed in Huntingtons disease (HD). The use of 3-NPA in animal models of HD was prompted by findings that accidental ingestion of this toxin produces striatal degeneration that resembles what is observed in the brains of HD patients. In the mid-1970s, 3-NPA was isolated as the toxic substance in locoweed and milkvetches responsible for the widespread poisoning of domestic livestock (1,2). However, its significance as a potential tool for gaining a better understanding of HD was catapulted by reports of its effects on children in China who were exposed to it after ingesting moldy sugarcane (3,4). Some of these children displayed dystonia, or severe plastic rigidity, including a tonic flexion of the arms and legs. The computed tomography (CT) scans of these children revealed bilateral basal ganglia hypodensity (3,5). These findings suggested that 3-NPA could be a useful tool for studying mechanisms of neuronal damage, particularly for neurodegenerative diseases, such as HD. Although several laboratories have demonstrated that acute intrastriatal injections and chronic systemic administration of 3-NPA accurately reproduce many of the neuropathological characteristics of HD (6-13), relatively little is known about the behavioral effects of 3-NPA, particularly its effect on cognitive processing. Interest in our laboratory has focused on the use of 3-NPA in an animal model of neurodegeneration that mimics some of the behavioral as well as the neuropathological symptoms of HD. This chapter focuses on what is known about the behavioral effects of acute intrastriatal and chronic systemic injections of 3-NPA in animal models of HD. We present some of the recent findings in our laboratory within the context of what is already known about the effects of 3-NPA on cognitive and motor ability.