Although secondary delayed neuronal death has been considered as a therapeutic target to minimize brain damage induced by several injuries, delayed neuronal death does not occur always. In this study, we investigated possible mechanisms that prevent delayed neuronal death in the ATP-injected substantia nigra (SN) and cortex, where delayed neuronal death does not occur. In both the SN and cortex, ATP rapidly induced death of the neurons and astrocytes in the injection core area within 3 h, and the astrocytes in the penumbra region became hypertropic and rapidly surrounded the damaged areas. It was observed that the neurons survived for up to 1-3 months in the area where the astrocytes became hypertropic. The damaged areas of astrocytes gradually reduced at 3 days, 7 days, and 1-3 months. Astrocyte proliferation was detectable at 3-7 days, and vimentin was expressed in astrocytes that surrounded and/or protruded into the damaged sites. The NeuN-positive cells also reappeared in the injury sites where astrocytes reappeared. Taken together, these results suggest that astroycte survival and/or gliosis in the injured brain may be critical for neuronal survival and may prevent delayed neuronal death in the injured brain.
Adenosine Triphosphate ; Astrocytes ; Brain Injuries ; Brain* ; Gliosis ; Neurons* ; Substantia Nigra ; Vimentin

It has been suggested that brain inflammation is important in aggravation of brain damage and/or that inflammation causes neurodegenerative diseases including Parkinson's disease (PD). Recently, systemic inflammation has also emerged as a risk factor for PD. In the present study, we evaluated how systemic inflammation induced by intravenous (iv) lipopolysaccharides (LPS) injection affected brain inflammation and neuronal damage in the rat. Interestingly, almost all brain inflammatory responses, including morphological activation of microglia, neutrophil infiltration, and mRNA/protein expression of inflammatory mediators, appeared within 4-8 h, and subsided within 1-3 days, in the substantia nigra (SN), where dopaminergic neurons are located. More importantly, however, dopaminergic neuronal loss was not detectable for up to 8 d after iv LPS injection. Together, these results indicate that acute induction of systemic inflammation causes brain inflammation, but this is not sufficiently toxic to induce neuronal injury.
Animals ; Astrocytes/pathology ; Cell Death ; Encephalitis/chemically induced/immunology/*pathology ; Injections, Intravenous ; Lipopolysaccharides/*pharmacology ; Male ; Microglia/pathology ; Neutrophil Infiltration ; Rats ; Rats, Sprague-Dawley ; Substantia Nigra/immunology/*pathology

The inflammation that accompanies acute injury has dual functions: bactericidal action and repair. Bactericidal functions protect damaged tissue from infection, and repair functions are initiated to aid in the recovery of damaged tissue. Brain injury is somewhat different from injuries in other tissues in two respects. First, many cases of brain injury are not accompanied by infection: there is no chance of pathogens to enter in ischemia or even in traumatic injury if the skull is intact. Second, neurons are rarely regenerated once damaged. This raises the question of whether bactericidal inflammation really occurs in the injured brain; if so, how is this type of inflammation controlled? Many brain inflammation studies have been conducted using cultured microglia (brain macrophages). Even where animal models have been used, the behavior of microglia and neurons has typically been analyzed at or after the time of neuronal death, a time window that excludes the inflammatory response, which begins immediately after the injury. Therefore, to understand the patterns and roles of brain inflammation in the injured brain, it is necessary to analyze the behavior of all cell types in the injured brain immediately after the onset of injury. Based on our experience with both in vitro and in vivo experimental models of brain inflammation, we concluded that not only microglia, but also astrocytes, blood inflammatory cells, and even neurons participate and/or regulate brain inflammation in the injured brain. Furthermore, brain inflammation played by these cells protects neurons and repairs damaged microenvironment but not induces neuronal damage.
Astrocytes ; Brain ; Brain Injuries ; Encephalitis ; Inflammation ; Ischemia ; Microglia ; Models, Animal ; Models, Theoretical ; Neurons ; Skull

This study was to determine the effects of allogenicumbilical cord blood (UCB)-derived mesenchymal stemcells (MSCs) and recombinant methionyl humangranulocyte colony-stimulating factor (rmhGCSF) on acanine spinal cord injury model after balloon compressionat the first lumbar vertebra. Twenty-five adult mongreldogs were assigned to five groups according to treatmentafter a spinal cord injury: no treatment (CN); salinetreatment (CP); rmhGCSF treatment (G); UCB-MSCstreatment (UCB-MSC); co-treatment (UCBG). The UCB-MSCs isolated from cord blood of canine fetuses wereprepared as 10(6) cells/150microl saline. The UCB-MSCs weredirectly injected into the injured site of the spinal cord andrmhGCSF was administered subcutaneously 1 week afterthe induction of spinal cord injury. The Olby score,magnetic resonance imaging, somatosensory evokedpotentials and histopathological examinations were used toevaluate the functional recovery after transplantation. TheOlby scores of all groups were zero at the 0-week evaluation.At 2 week after the transplantation, the Olby scores in thegroups with the UCB-MSC and UCBG were significantlyhigher than in the CN and CP groups. However, there wereno significant differences between the UCB-MSC andUCBG groups, and between the CN and CP groups. Thesecomparisons remained stable at 4 and 8 week aftertransplantation. There was significant improvement in thenerve conduction velocity based on the somatosensory evokedpotentials. In addition, a distinct structural consistency ofthe nerve cell bodies was noted in the lesion of the spinalcord of the UCB-MSC and UCBG groups. These resultssuggest that transplantation of the UCB-MSCs resulted inrecovery of nerve function in dogs with a spinal cord injuryand may be considered as a therapeutic modality for spinalcord injury.
Animals ; Behavior, Animal/physiology ; Cord Blood Stem Cell Transplantation/methods/*veterinary ; Dog Diseases/pathology/*therapy ; Dogs ; Evoked Potentials, Somatosensory/physiology ; Histocytochemistry/veterinary ; Magnetic Resonance Imaging/veterinary ; Random Allocation ; Spinal Cord Injuries/pathology/therapy/*veterinary ; Videotape Recording

Parkinson's disease (PD) is the second most common neurodegenerative motor disease caused by degeneration of dopaminergic neurons in the substantia nigra. Because brain inflammation has been considered a risk factor for PD, we analyzed whether PTEN induced putative kinase 1 (PINK1), an autosomal recessive familial PD gene, regulates brain inflammation during injury states. Using acutely prepared cortical slices to mimic injury, we analyzed expression of the pro-inflammatory cytokines tumor necrosis factor-alpha, interleukin (IL)-1beta, and IL-6 at the mRNA and protein levels. Both mRNA and protein expression of these cytokines was higher at 6-24 h after slicing in PINK1 knockout (KO) slices compared to that in wild-type (WT) slices. In serial experiments to understand the signaling pathways that increase inflammatory responses in KO slices, we found that IkappaB degradation was enhanced but Akt phosphorylation decreased in KO slices compared to those in WT slices. In further experiments, an inhibitor of PI3K (LY294002) upstream of Akt increased expression of pro-inflammatory cytokines. Taken together, these results suggest that PINK1 deficiency enhance brain inflammation through reduced Akt activation and enhanced IkappaB degradation in response to brain injury.
Brain ; Brain Injuries ; Cytokines ; Dopaminergic Neurons ; Encephalitis ; Hydrazines ; Inflammation ; Interleukin-6 ; Interleukins ; Parkinson Disease ; Phosphorylation ; Phosphotransferases ; Risk Factors ; RNA, Messenger ; Substantia Nigra ; Tumor Necrosis Factor-alpha

In this study, we evaluated if the implantation of allogenic adipose-derived stem cells (ASCs) improved neurological function in a canine spinal cord injury model. Eleven adult dogs were assigned to three groups according to treatment after spinal cord injury by epidural balloon compression: C group (no ASCs treatment as control), V group (vehicle treatment with PBS), and ASC group (ASCs treatment). ASCs or vehicle were injected directly into the injured site 1 week after spinal cord injury. Pelvic limb function after transplantation was evaluated by Olby score. Magnetic resonance imaging, somatosensory evoked potential (SEP), histopathologic and immunohistichemical examinations were also performed. Olby scores in the ASC group increased from 2 weeks after transplantation and were significantly higher than C and V groups until 8 weeks (p<0.05). However, there were no significant differences between the C and V groups. Nerve conduction velocity based on SEP was significantly improved in the ASC group compared to C and V groups (p < 0.05). Positive areas for Luxol fast blue staining were located at the injured site in the ASC group. Also, GFAP, Tuj-1 and NF160 were observed immunohistochemically in cells derived from implanted ASCs. These results suggested that improvement in neurological function by the transplantation of ASCs in dogs with spinal cord injury may be partially due to the neural differentiation of implanted stem cells.
Adipose Tissue/*cytology ; Animals ; Cell Differentiation ; Dog Diseases/pathology/*therapy ; Dogs ; Neurons/*cytology ; Spinal Cord Injuries/therapy/*veterinary ; Stem Cell Transplantation/*veterinary ; Stem Cells/*cytology/physiology

Purpose: Single-photon emission computed tomography/computed tomography (SPECT/CT) is an advanced hybrid nuclear medicine technology that generates both functional and anatomical images in a single study. As utilization of SPECT/CT in Korea has been increasing, the purpose of this study was to survey its application of cardiac and skeletal SPECT/CT imaging for protocol optimization. Methods: We surveyed CT protocols established for cardiac and skeletal SPECT/CT. We searched the guidelines for the CT protocols for SPECT/CT and reviewed the literature recently published. Results: Among 36 hybrid SPECT scanners equipped with four or more multi-channel detector CTs (MDCTs), 18 scanners were used to perform cardiac studies at both very low current CT (30–80 mA; 11.1%) and ultra-low current CT (13–30 mA; 88.9%). Among the 33 canners, very low current (≤ 80 mA) CT or low current CT (80–130 mA) was used in 23.5%, and 41.8% for spine disorders, and in 36.4% or 30.3% for foot/ankle disorders, respectively. In the CT reconstructions, slice thickness of 5 mm for cardiac studies was most commonly used (94.4%); thinner slices (0.6–1.0 mm) for spine and foot/ankle studies were used in 24.2% and 45.5%, respectively. We also reviewed the international guidelines. Conclusions The results and current recommendations will be helpful for optimizing CT protocols for SPECT/CT. Optimization of SPECT/CT protocols will be required for generating the proper strategy for the specific lesions and clinical purpose.