Analysis of glucose metabolism by 18F-FDG-PET imaging and glucose transporter expression in a mouse model of intracerebral hemorrhage

The relationship between cerebral glucose metabolism and glucose transporter expression after intracerebral hemorrhage (ICH) is unclear. Few studies have used positron emission tomography (PET) to explore cerebral glucose metabolism after ICH in rodents. In this study, we produced ICH in mice with an intrastriatal injection of collagenase to investigate whether glucose metabolic changes in 18F-fluoro-2-deoxy-D-glucose (FDG)-PET images are associated with expression of glucose transporters (GLUTs) over time. On days 1 and 3 after ICH, the ipsilateral striatum exhibited significant hypometabolism. However, by days 7 and 14, glucose metabolism was significantly higher in the ipsilateral striatum than in the contralateral striatum. The contralateral hemisphere did not show hypermetabolism at any time after ICH. Qualitative immunofluorescence and Western blotting indicated that the expression of GLUT1 in ipsilateral striatum decreased on days 1 and 3 after ICH and gradually returned to baseline by day 21. The 18F-FDG uptake after ICH was associated with expression of GLUT1 but not GLUT3 or GLUT5. Our data suggest that ipsilateral cerebral glucose metabolism decreases in the early stage after ICH and increases progressively in the late stage. Changes in 18F-FDG uptake on PET imaging are associated with the expression of GLUT1 in the ipsilateral striatum.

Convergence of forepaw somatosensory and motor cortical projections in the striatum, claustrum, thalamus, and pontine nuclei of cats

The basal ganglia and pontocerebellar systems regulate somesthetic-guided motor behaviors, and receive prominent inputs from sensorimotor cortex. Additionally, the claustrum and thalamus are forebrain subcortical structures that have connections with somatosensory and motor cortices. Our previous studies in rats have shown that primary and secondary somatosensory cortex (S1 and S2) send overlapping projections to the neostriatum and pontine nuclei, whereas overlap of primary motor cortex (M1) and S1 was much weaker. Additionally, we have shown that M1, but not S1, projects to the claustrum in rats. The goal of the current study was to compare these rodent projection patterns with connections in cats, a mammalian species that evolved in a separate phylogenetic superorder. Three different anterograde tracers were injected into the physiologically identified forepaw representations of M1, S1, and S2 in cats. Labeled fibers terminated throughout the ipsilateral striatum (caudate and putamen), claustrum, thalamus, and pontine nuclei. Digital reconstructions of tracer labeling allowed us to quantify both the normalized distribution of labeling in each subcortical area from each tracer injection, as well as the amount of tracer overlap. Surprisingly, in contrast to our previous findings in rodents, we observed M1 and S1 projections converging prominently in striatum and pons, whereas S1 and S2 overlap was much weaker. Furthermore, whereas rat S1 does not project to claustrum, we confirmed dense claustral inputs from S1 in cats. These findings suggest that the basal ganglia, claustrum, and pontocerebellar systems in rat and cat have evolved distinct patterns of sensorimotor cortical convergence.

Abstract 52: Changes in Oligodendrocyte Sub-Populations After Neonatal Stroke

Background: Chronic white matter changes after neonatal stroke have not been well studied. Histologically, we see a robust increase in oligodendrocytes (OLs) in injured striatum 14 days post-middle cerebral artery occlusion (MCAO) in neonatal mice. The contribution of these cells to chronic white matter injury and repair has not been evaluated. Objective: Evaluate changes in striatal OL cell gene expression after neonatal MCAO. Methods: Mice underwent 60 minutes of MCAO at postnatal day 10 using the filament model and sacrificed 14 days later for fluorescent antibody cell sorting and single cell RNA sequencing. Single cell suspensions from Injured (ipsilateral) and uninjured (contralateral) striata were incubated with antibodies to immature and mature OLs. Cells expressing OL markers were collected and captured using 10x Genomics Chromium with V3.1 chemistry and analyzed in Seurat V3.1. Results: We captured a total of 4598 cells, with ~250,000 reads per cell. Our data set was comprised of 2399 oligodendrocytes (915 Contralateral, 1484 Ipsilateral). Feature plots of OL markers demonstrate that the entire lineage is present in our cell population (Fig 1A). Unbiased clustering identified 10 sub-populations of oligodendrocytes (Fig 1B). In ipsilateral striatum there was a significant decrease in the proportion of cells in cluster 8 (p <0.0001, proportions test, Fig 1C), which also express OL progenitor cell (OPC) markers. There was a significant increase in the proportion of cells in clusters 1 and 5. Pathway analysis suggest that both these clusters are comprised of pre-myelinating oligodendrocytes. Conclusions: At 14 days after neonatal stroke in mice scSEQ reveals a depletion of an OPC sub-population and an increase in sub-mature clusters of oligodendrocytes in ipsilateral striatum. Ongoing analysis of differential gene expression will reveal new insights into these cells and potential targets to promote white matter repair after neonatal stroke.

Deficits in motor and cognitive functions in an adult mouse model of hypoxia-ischemia induced stroke

Ischemic strokes cause devastating brain damage and functional deficits with few treatments available. Previous studies have shown that the ischemia-hypoxia rapidly induces clinically similar thrombosis and neuronal loss, but any resulting behavioral changes are largely unknown. The goal of this study was to evaluate motor and cognitive deficits in adult HI mice. Following a previously established procedure, HI mouse models were induced by first ligating the right common carotid artery and followed by hypoxia. Histological data showed significant long-term neuronal losses and reactive glial cells in the ipsilateral striatum and hippocampus of the HI mice. Whereas the open field test and the rotarod test could not reliably distinguish between the sham and HI mice, in the tapered beam and wire-hanging tests, the HI mice showed short-term and long-term deficits, as evidenced by the increased number of foot faults and decreased hanging time respectively. In cognitive tests, the HI mice swam longer distances and needed more time to find the platform in the Morris water maze test and showed shorter freezing time in fear contextual tests after fear training. In conclusion, this study demonstrates that adult HI mice have motor and cognitive deficits and could be useful models for preclinical stroke research.

Abstract TP337: Microglial Activation and Neuroinflammation Are Mediated by Over-Activation of Cofilin After Intracerebral Hemorrhage

Intracerebral hemorrhage (ICH) is a major health concern associated with high mortality and morbidity. 50% of the stroke victims die within the first month and the rest of the survivors have to deal with long-term disabilities. The understanding of the molecular mechanism of the secondary injury-induced neuroinflammation or microglial activation is not studied well. Our previous study demonstrated a major causative role of the cytoskeletal protein, cofilin in ICH-induced brain injury. We demonstrated that knockdown of cofilin in a mouse model of collagenase induced-ICH improved neurobehavioral deficits, decreased hemorrhagic volume and microglia activation. In the present study, we aimed to study the cofilin signaling up to 14 days following ICH. We subjected different cohorts of mice to intrastriatal collagenase injection-induced ICH and mice were sacrificed at different time-points of 1, 3, 7, and 14 days. Using Western blotting (WB) and quantitative real-time PCR, we observed an upregulation of cofilin protein and mRNA levels in the ipsilateral striatum on day 3 and then a decreasing trend was observed from day 7 to day 14. Using immunohistochemistry analysis, activated microglia were observed to be increased after ICH from day 1, especially around the hematoma and lasted until day 7 and there was a gradual decrease observed at day 14. Activated microglia were associated with morphological changes from ramified into an amoeboid shape particularly around the hematoma from day 1 up to day 14. Human ICH autopsy brain sections also indicated that intracellular cofilin is localized within microglia and is associated with microglia morphological changes and activation of surrounding microglia. In conclusion, we believe that cofilin overactivation plays a causative role in the activation of microglia and subsequently leads to widespread neuroinflammation following ICH. Developing cofilin inhibitors might provide novel alternatives for ICH treatment.

Abstract TP112: Delayed Oligodendrocyte Maturation Corresponds to Myelin and Motor Recovery After Neonatal Stroke

Introduction: Neonatal stroke is a common cause of lifelong neurologic disability. White matter repair after neonatal stroke has been understudied. Objective: Characterize acute myelin injury within striatal white matter and determine if endogenous remyelination occurs chronically. Methods: Postnatal day 10 (p10) mice underwent MCAO for 60 minutes, followed by reperfusion, and animals were sacrificed on post-op day (POD) 3, 14 or 28. Immunohistochemistry (IHC) was used to assess oligodendrocyte maturation, and white matter integrity. Gait was assessed on POD 14 or 30. Results: On POD3 there is a significant decrease in neuronal density in the ipsilateral striatum compared to contralateral. There is also a significant reduction in mature oligodendrocytes density. At this timepoint, axons are preserved (measured as %SMI34 + pixels), but there is significant myelin loss (measured as %MBP + pixels) in the ipsilateral striatum (fig 1A-D). On POD 14 there is persistently decreased myelin density in ipsilateral striatum compared to contralateral, and the proportion of oligodendrocytes with a mature phenotype (Olig2 + CC1 + /Olig2 + ) is significantly lower. Both myelin density and maturational index of oligodendrocytes recover by POD 28. At fourteen days after MCAO there is a significant reduction in gait length on the left side, which recovers by 28 days (fig1 E-G). Conclusions: 60 minute MCAO in neonatal mice produces striatal injury with oligodendrocyte and myelin loss but preservation of axons, providing a substrate for repair. Myelin deficit persists at 14 days, and there is an oligodendrocyte maturational delay at this same time. Myelination and oligodendrocyte maturation recover between 14 and 28 days, corresponding to recovery of motor function. Future studies will focus on whether interventions that accelerate oligodendrocyte maturation and re-myelination can improve early functional outcome.

Differential Striatal Axonal Arborizations of the Intratelencephalic and Pyramidal-Tract Neurons: Analysis of the Data in the MouseLight Database

There exist two major types of striatum-targeting neocortical neurons, specifically, intratelencephalic (IT) neurons and pyramidal-tract (PT) neurons. Regarding their striatal projections, it was once suggested that IT axons are extended whereas PT axons are primarily focal. However, subsequent study with an increased number of well-stained extended axons concluded that such an apparent distinction was spurious due to limited sample size. Recent work using genetically labeled neurons reintroduced the differential spatial extent of the striatal projections of IT and PT neurons through population-level analyses, complemented by observations of single axons. However, quantitative analysis of a large number of axons remained to be conducted. We analyzed the data of axonal end-points of 161 IT neurons and 33 PT neurons in the MouseLight database (http://ml-neuronbrowser.janelia.org/). The number of axonal end-points in the ipsilateral striatum exhibits roughly monotonically decreasing distributions in both neuron types. However, the proportion of neurons having >50 ipsilateral end-points is larger in IT neurons than in PT neurons. Moreover, distinguishing IT subpopulations in the secondary motor area (MOs), layer 5 neurons and bilateral striatum-targeting layer 2/3 neurons, but not contralateral striatum-non-targeting layer 2/3 neurons, have a larger number of ipsilateral end-points than MOs PT neurons. We also found that IT ipsilateral striatal axonal end-points are on average more widely distributed than PT end-points, especially in the medial-lateral direction. These results indicate that IT and PT striatal axons differ in the frequency of having numerous end-points and the spatial extent of end-points while there are wide varieties within each neuron type.

Preserved Cerebral Oxygen Metabolism in Astrocytic Dysfunction: A Combination Study of 15O-Gas PET with 14C-Acetate Autoradiography

Fluorocitrate (FC) is a specific metabolic inhibitor of the tricarboxylic acid (TCA) cycle in astrocytes. The purpose of this study was to evaluate whether inhibition of the astrocyte TCA cycle by FC would affect the oxygen metabolism in the rat brain. At 4 h after the intracranial FC injection, the rats (n = 9) were investigated by 15O-labeled gas PET to measure the cerebral blood flow (CBF), the cerebral metabolic rate of oxygen (CMRO2), oxygen extraction fraction (OEF), and cerebral blood volume (CBV). After the 15O-gas PET, the rats were given an intravenous injection of 14C-acetate for autoradiography. 15O-gas PET showed no significant differences in any of the measured parameters between the ipsilateral and contralateral striatum (high dose group: CBF (54.4 ± 8.8 and 55.3 ± 11.6 mL/100 mL/min), CMRO2 (7.0 ± 0.9 and 7.1 ± 1.2 mL/100 mL/min), OEF (72.0 ± 8.9 and 70.8 ± 8.2%), and CBV (4.1 ± 0.8 and 4.2 ± 0.9 mL/100 mL), respectively). In contrast, the 14C-acetate autoradiography revealed a significant inhibition of the astrocyte metabolism in the ipsilateral striatum. The regional cerebral oxygen consumption as well as the hemodynamic parameters were maintained even in the face of inhibition of the astrocyte TCA cycle metabolism in the rat brain.

Botulinum Neurotoxin-A Injected Intrastriatally into Hemiparkinsonian Rats Improves the Initiation Time for Left and Right Forelimbs in Both Forehand and Backhand Directions

Forelimb stepping is a widely used test for the assessment of forelimb akinesia in hemiparkinsonian (hemi-PD) rats. The initiation time (IT) is considered the most sensitive parameter in the stepping test procedure. Here we propose a novel, reliable, and simple method for the measurement of IT of both forelimbs in both forehand and backhand directions in rats. Evaluating the same videos taken for quantifying adjusting steps, IT measurements were done without additional experiments. This is in contrast to the classical approach introduced by Olsson et al. (1995), in which separate experiments are necessary. We successfully applied our approach to hemi-PD rats intrastriatally treated with botulinum neurotoxin-A (BoNT-A). In naïve rats, an IT of about 0.62 s was found, and in right-sided hemi-PD rats the IT of the left forepaw increased to about 3.62 s. These hemi-PD rats showed, however, reduced ITs of the impaired left forepaws 1 month and the second time 7 months after induction of hemi-PD via the injection of 1 ng BoNT-A into the ipsilateral striatum, depending on post BoNT-A survival time. The method described offers the possibility of a precise and animal-friendly evaluation of IT in rats, including the beneficial effect of BoNT-A treatment in hemi-PD rats.

Neuroplasticity induction using transcranial magnetic stimulation

In this article, we have displayed the results of an analysis of modern scientific data on the induction of neuroplasticity using transcranial magnetic stimulation. We presented the multilevel neuroplastic effects of electromagnetic fields caused by transcranial magnetic stimulation (TMS). The authors of the article determined that transcranial magnetic stimulation uses variable magnetic fields to non-invasively stimulate neurons in the brain. The basis of this method is the modulation of neuroplasticity mechanisms with the subsequent reorganization of neural networks. Repeated TMS (rTMS), which is widely used in neurology, affects neurotransmitters and synaptic plasticity, glial cells and the prevention of neuronal death. The neurotrophic effects of rTMS on dendritic growth, as well as growth and neurotrophic factors, are described. An important aspect of the action of TMS is its effect on neuroprotective mechanisms. A neuroimaging study of patients with Parkinson's disease showed that rTMS increased the concentration of endogenous dopamine in the ipsilateral striatum. After rTMS exposure, the number of β-adrenergic receptors in the frontal and cingulate cortex decreases, but the number of NMDA receptors in the ventromedial thalamus, amygdala, and parietal cortex increases. These processes ultimately lead to the induction of prolonged potentiation. In response to rTMS, neuronal excitability changes due to a shift in ion balance around a population of stimulated neurons; this shift manifests itself as altered synaptic plasticity. Combinations of rTMS treatment and pharmacotherapy (e.g., small doses of memantine) may block the alleviating effect during prolonged potentiation. Studies using models of transient ischemic attack and prolonged ischemia have shown that rTMS protects neurons from death and alters the blood flow and metabolism in the brain. It has been demonstrated that TMS has a proven ability to modulate the internal activity of the brain in a frequency-dependent manner, generate contralateral responses, provide, along with the neuromodulating and neurostimulating effect, affect the brain as a global dynamic system.