Radiation-induced edema is dependent on cyclooxygenase 2 activity in mouse brain

Cerebrovascular dysfunction, characterized by compromise of the blood-brain barrier and formation of cerebral edema, is common during the acute period after brain irradiation and may contribute to delayed pathology (e.g. vascular collapse, white matter necrosis) that leads to functional deficits. Another response of normal brain tissue to radiation is the induction of inflammatory markers, such as cytokine expression and glial activation. In particular, radiation-induced neuroinflammation is associated with an elevation in cyclooxygenase 2 (COX2), one of two isoforms of the obligate enzyme in prostanoid synthesis and the principal target of non-steroid anti-inflammatory drugs. Since prostanoids serve as autocrine and paracrine mediators in numerous physiological and pathological processes, including vasoregulation, we investigated COX2 protein expression and COX2-mediated prostanoid production in radiation-induced cerebral edema in male C57/BL6 mice. We found that radiation induces COX2 protein that is accompanied by specific increases in prostaglandin E(2) and thromboxane A(2) within 4 and 24 h after brain irradiation. Furthermore, we showed that treatment with NS-398, a selective COX2 inhibitor, attenuated prostanoid induction and edema formation. These results suggest that radiation-induced changes in vascular permeability are dependent on COX2 activity, implicating this enzyme and its products as targets for potential therapeutic treatment/protection from the effects of radiation on normal brain tissue.     

Cerebrovascular response after interstitial irradiation.

To characterize the role of the cerebrovascular response in the development of brain injury after focal irradiation, 125I sources were implanted in frontal white matter of the brain of normal dogs; dose was 20 Gy, 7.5 mm from the source. Cerebral blood flow, vascular volume and mean transit time of blood were quantified in irradiated tissues relative to tissues in the contralateral hemisphere and analyzed with respect to previously determined volumetric measurements of damage and the blood-to-brain transfer constant. Blood flow and vascular volume within the radiation-induced focal lesion were maximally reduced 3 weeks after implant, when necrosis volume was maximal. By 6 weeks, vascular volume and mean transit time were increased, suggesting a strong neovascular response. In tissues surrounding the lesion, blood flow and vascular volume were reduced 1-4 weeks after irradiation and approached normal at 6 weeks; average mean transit time was not altered significantly. Alterations in blood flow and mean transit time were significantly related to edema volume and transfer constant, but alterations in vascular volume were not, suggesting that edema-induced vascular compression was not responsible for changes in blood flow. Reductions of radiation-induced permeability of the blood-brain barrier and/or edema might limit radiation-induced changes in blood flow and the extent of tissue injury.     

Chronic histological effects of ultrasonic hyperthermia on normal feline brain tissue

The histopathological changes associated with ultrasonic heating of normal cat brain have been correlated with thermal distributions. Ultrasound energy was applied for 50 min at different intensities to generate tissue temperatures from 42 to 48 degrees C. Animals were sacrificed at various intervals from 1 to 56 days. The organization and resolution of thermal damage was characterized by three stages of histopathological changes within the nervous tissue. The acute stage (Days 1-3) was defined by (1) extensive coagulation necrosis, (2) pyknosis of neuronal elements in the gray matter, (3) edema and vacuolation in the white matter, and (4) polymorphonuclear leukocytes. The subacute stage (Days 3-21) was characterized by (1) the appearance of lipid-laden macrophages, (2) liquefaction of the necrotic regions, (3) fibroblastic proliferation, and (4) vascular proliferation with some perivascular inflammatory infiltration (lymphocytes). Lastly, the chronic stage (Days 21-56) was defined by (1) fibrosis (reticulin and collagen formation) and (2) gliosis (reactive astrocytic proliferation) occurring around the fluid-filled necrotic center. Analysis of these data has also included a study of the lesion size versus the dose (temperature for 50 min) of heating. The results demonstrate a significant linear dose-response correlation. The results of this study indicate that the histological appearance and time course of repair of thermal injury in the normal brain tissue are analogous to acute brain necrosis resulting from cerebral infarction, except the thermal damage does not result in significant hemorrhage.     

Differential protein expression in the corpus callosum (splenium) of human alcoholics: a proteomics study

It is widely accepted that the chronic use of alcohol induces metabolic abnormalities and neuronal damage in the brain, which can lead to cognitive dysfunction. Neuroimaging studies reveal that alcohol-induced brain damage is region specific and prominent damage has been observed in both gray and white matter of the prefrontal cortex, and a wide range of white matter structures including the corpus callosum. Molecular mechanisms underlying these structural changes are largely unknown. Using proteomics we have analysed the changes in protein expression in the splenium of the corpus callosum in two different alcoholic groups. Protein extracts from splenium of 22 human brains (nine controls, seven uncomplicated alcoholics and six complicated alcoholics with hepatic cirrhosis-designated complicated) were separated using two-dimensional gel electrophorosis. Image analysis revealed that there were significant alterations in protein expression for 25 protein spots in the uncomplicated alcoholic group and 45 in the complicated group compared to control (P<0.05; ANOVA). In a total of 72 spots (identified as 36 proteins), 15 (identified as 14 proteins) spots overlapped between two alcoholic groups. Another 32 protein spots (26 different proteins) were identified only in the complicated alcoholics. It is therefore possible that these 26 proteins in the complicated group are likely to be the results of hepatic compromise. When compared with our previous data of white matter from the prefrontal cortex in alcoholics, large numbers of identified proteins in the splenium are different. This suggests that there may be different mechanisms causing alcohol-induced brain damage in different regions of the white matter. Our data also indicate the importance of other pathways including oxidative stress, lipid peroxidation and apoptosis as potential causes of alcohol-induced brain damage.     

Dolichol in Human Brain: Regional and Developmental Aspects

Distinct regional differences in dolichol content were defined in human brain from 15 to 76 years of age. Concerning the regional distribution of dolichol, levels were: higher in cortical gray matter than in subcortical white matter, highest among cortical regions in temporal gray matter, highest among all brain regions in thalamus, and lowest among all brain regions in lower brain stem and spinal cord. The developmental changes in the contents of dolichol were found to be different among brain regions. For example, among regions with the highest levels of dolichol, in thalamus there was a six to sevenfold increase, but in parietal gray matter, only a 2.5-fold increase. Regional and developmental changes in the proportions of the individual molecular species (isoprenologues) of dolichol were also observed. The findings indicate that the metabolism of dolichol is not uniform among regions of developing and aging human brain and may have implications for the role of dolichol in normal and diseased human brain.     

Cystic hygroma colli as the first echographic sign of the fetal akinesia sequence

We report first trimester cystic hygroma colli with subsequent resolution and development of a fetal akinesia deformation sequence. Neuropathological examination of the brain showed intra- and extracellular white matter edema while spinal cord, peripheral nerves and muscles were normal. Hygroma colli as the first echographic sign of subsequent severe fetal akinesia sequence without muscular dystrophy as seen in the Lethal Multiple Pterygium syndrome has not been previously reported.     

Brain Ion and Amino Acid Contents During Edema Development in Hepatic Encephalopathy

Abstract: Brain edema in hepatic encephalopathy has been associated with circulating ammonia that is metabolized to glutamine. We measured alterations in blood chemistry and brain regional specific gravity and ion and amino acid contents in models of simple hyperammonemia and liver failure induced by daily administrations of ammonium acetate (AAc) or thioacetamide (TAA), respectively. Serum and brain ammonia increased to similar levels (200 and 170% of control, respectively) in both experimental groups. Serum transaminase activities increased 10-fold in animals injected with TAA but were unchanged in animals given AAc injections. In both experimental groups glutamine was elevated in cerebral white matter, cerebral gray matter, and basal ganglia, whereas brain tissue specific gravity decreased in all brain regions, indicating edema formation. In the AAc group, we observed a decrease in glutamate and taurine contents concomitant with the development of brain edema. In these animals, cerebral gray matter specific gravity and taurine contents returned to control levels 24 h after the third AAc injection. TAA-injected animals demonstrated similar decreases in brain tissue specific gravity, whereas glutamine, glutamate, and taurine contents were all elevated. During hepatic encephalopathy, ammonia-induced changes in brain amino acid content may contribute to brain edema development.     

Orientation Dependent MR Signal Decay Differentiates between People with MS,Their Asymptomatic Siblings and Unrelated Healthy Controls

R2* relaxometry of the brain is a quantitative magnetic resonance technique which is influenced by iron and myelin content across different brain regions. Multiple sclerosis (MS) is a common inflammatory, demyelinating disease affecting both white and grey matter regions of the CNS. Using R2*, increased iron deposition has been described in deep gray matter of MS patients. Iron accumulation might promote oxidative stress in the brain, which can lead to cell death and neurodegeneration. However, recent histological work indicates that iron may be reduced within the normal appearing white matter (WM) in MS. In the present study we analyzed the R2* signal across the white matter in 39 patients with MS, 31 asymptomatic age matched siblings of patients and 30 age-matched controls. The measurement of R2* in white matter is affected by the signal''s dependency on white matter fibre orientation with respect to the main magnetic field which can be accounted using diffusion tensor imaging. We observed a clear separation of the three study groups in R2*. The values in the MS group were significantly lower compared to the siblings and controls, while the siblings group presented with significantly higher R2* values than both unrelated healthy controls and patients. Furthermore, we found significantly decreased normal-appearing white matter R2* values in patients with more severe disease course. Angle resolved analysis of R2* improves the sensitivity for detecting subtle differences in WM R2* compared to standard histogram based analyses. Our findings suggest that the decreased R2* values in MS are due to diffuse tissue damage and decreased myelin in the normal appearing and diffusely abnormal WM. The increased R2* in unaffected siblings may identify a predisposition to increased iron and the potential for oxidative stress as a risk factor for developing MS.     

Residual stress in the adult mouse brain

This work provides direct evidence that sustained tensile stress exists in white matter of the mature mouse brain. This finding has important implications for the mechanisms of brain development, as tension in neural axons has been hypothesized to drive cortical folding in the human brain. In addition, knowledge of residual stress is required to fully understand the mechanisms behind traumatic brain injury and changes in mechanical properties due to aging and disease. To estimate residual stress in the brain, we performed serial dissection experiments on 500-mum thick coronal slices from fresh adult mouse brains and developed finite element models for these experiments. Radial cuts were made either into cortical gray matter, or through the cortex and the underlying white matter tract composed of parallel neural axons. Cuts into cortical gray matter did not open, but cuts through both layers consistently opened at the point where the cut crossed the white matter. We infer that the cerebral white matter is under considerable tension in the circumferential direction in the coronal cerebral plane, parallel to most of the neural fibers, while the cerebral cortical gray matter is in compression. The models show that the observed deformation after cutting can be caused by more growth in the gray matter than in the white matter, with the estimated tensile stress in the white matter being on the order of 100–1,000 Pa.     

Modification of radiation-induced brain injury by alpha-difluoromethylornithine

The effect of alpha-difluoromethylornithine (DFMO) on 125I-induced brain injury was investigated in a dog model. Cerebrospinal putrescine levels were reduced from baseline levels 1-2 weeks after irradiation in animals treated with 125I and DFMO, while putrescine levels were elevated in 125I and saline-treated animals. In addition, the time course of changes in the volumes of edema, necrosis, and tissue showing evidence of blood-brain barrier breakdown was altered significantly by DFMO treatment. The most significant alterations occurred 2-4 weeks after irradiation, at which times the average volumes of damage in DFMO-treated animals were reduced compared to saline-treated animals. The time course of alterations in blood-to-brain transfer, brain-to-blood transfer, and vascularity following irradiation was also altered by DFMO treatment. Analysis of variance demonstrated a strong relationship of blood-to-brain transfer and vascularity to volume of edema, suggesting that the effect of DFMO on edema may be partially mediated by its effects on blood-brain barrier breakdown.     

d-Aspartate in Human Brain

The presence of the biologically uncommon D-aspartic acid (D-aspartate) in human brain white matter has been previously reported. The earlier study has now been expanded to include D/L-aspartate ratios from 67 normal brains. The data show that the D-aspartate content increases rapidly from 1 year to approximately 35 years of age, levels off in middle age, and then appears to decrease somewhat. The D-aspartate content in gray matter remains at a consistently low level (half of that found in white matter) throughout the human life span. Within the limitations of current analytical methods, there was no detectable difference in D/L-aspartate ratios in white and gray matter of brains with Alzheimer's disease and several other pathologies when compared with brains of normal subjects. However, the presence of a significant D-aspartate level in white matter during the adult life span may lead to changes in protein configuration related to dysfunctions associated with the aging brain.     

不同剂量MOG抗原免疫诱导小鼠自身免疫性脑脊髓炎模型的比较

目的比较不同剂量髓鞘少突胶质细胞糖蛋白(myelin oligodendrocyte glycoprotein,MOG35-55)免疫诱导C57BL/6小鼠实验性自身免疫性脑脊髓炎(experimental autoimmune encephalomyelitis,EAE)的作用。方法将C57BL/6小鼠分为正常组和三组不同剂量MOG35-55诱导的EAE模型组,共4组。模型组分别以每只200、100、50μg的MOG35-55与完全弗氏佐剂(complete Freund s adjuvant,CFA)混合的乳化抗原皮下注射免疫诱导EAE模型,正常组以生理盐水替代。观察不同剂量MOG35-55对C57BL/6小鼠体重、发病率以及神经功能评分等影响,同时取小鼠脑和脊髓,利用光镜和透射电镜观察小鼠病理组织学改变。结果三组不同剂量MOG35-55均能诱导EAE模型,发病率为100%,呈慢性单相病程,病理学观察发现小鼠脑和脊髓有炎性细胞浸润、脱髓鞘及轴突损伤等改变。但小剂量组在体重减轻、临床症状评分及病理学改变等方面均较中、大剂量组明显。结论用MOG35-5550μg剂量免疫诱导的C57BL/6小鼠EAE模型稳定,可在今后的研究中应用。     

Distribution of α-(γ-Aminobutyryl)-Hypusine

The distribution of alpha-(gamma-aminobutyryl)-hypusine was examined in several organs of the rabbit and in the brain of the rat, rabbit, dog, ox, and monkey. The peptide occurred only in the brains, but appeared to be absent from dog brain. Concentrations were higher in the cerebral hemispheres than in other portions of the brain. No significant difference between white and gray matter was observed.     

雨蛙素联合脂多糖致小鼠重症急性胰腺炎模型的建立及其机理的探讨

为建立一种快速、简便、无创伤性的小鼠重症急性胰腺炎模型。本实验运用雨蛙素联合脂多糖小鼠腹腔内给药;血淀粉酶和胰腺湿重测定;胰腺和胰外器官病理学检查;腺泡细胞透射电镜观察;血清NO浓度测定;胰腺组织SOD和MDA测定。结果发现,雨蛙素联合脂多糖组血淀粉酶、NO浓度和胰腺湿重均增高,SOD活力降低,MDA含量升高,胰腺间质水肿、实质出血坏死、炎症细胞浸润,腺泡细胞受损严重,胰外多器官受到不同程度的损害;雨蛙素组胰腺无明显出血坏死,胰外器官正常;脂多糖组胰腺基本正常,胰外器官轻微炎症浸润。由本实验结果显示,雨蛙素联合脂多糖致小鼠重症急性胰腺炎模型具有人类重症急性胰腺炎的病理特征,为非创伤性,成模快速稳定,重复性好;脂多糖促使雨蛙素诱导的急性水肿型胰腺炎重症化的机理与自由基释放-清除机制和氧化-抗氧化机制紊乱有关。     

雨蛙素联合脂多糖致小鼠重症急性胰腺炎模型的建立及其机理的探讨

为建立一种快速、简便、无创伤性的小鼠重症急性胰腺炎模型。本实验运用雨蛙素联合脂多糖小鼠腹腔内给药;血淀粉酶和胰腺湿重测定;胰腺和胰外器官病理学检查;腺泡细胞透射电镜观察;血清NO浓度测定;胰腺组织SOD和MDA测定。结果发现,丙蛙素联合脂多糖组血淀粉酶、NO浓度和胰腺湿重均增高,SOD活力降低,MDA含量升高,胰腺间质水肿、实质出血坏死、炎症细胞浸润,腺泡细胞受损严重,胰外多器官受到不同程度的损害;雨蛙素组胰腺无明显出血坏死,胰外器官正常;脂多糖组胰腺基本正常,胰外器官轻微炎症浸润。由本实验结果显示,丙蛙素联合脂多糖致小鼠重症急性胰腺炎模型具有人类重症急性胰腺炎的病理特征,为非创伤性,成模快速稳定,重复性好;脂多糖促使雨蛙素诱导的急性水肿型胰腺炎重症化的机理与自由基释放—清除机制和氧化—抗氧化机制紊乱有关。     

Mapping connectivity damage in the case of Phineas Gage

White matter (WM) mapping of the human brain using neuroimaging techniques has gained considerable interest in the neuroscience community. Using diffusion weighted (DWI) and magnetic resonance imaging (MRI), WM fiber pathways between brain regions may be systematically assessed to make inferences concerning their role in normal brain function, influence on behavior, as well as concerning the consequences of network-level brain damage. In this paper, we investigate the detailed connectomics in a noted example of severe traumatic brain injury (TBI) which has proved important to and controversial in the history of neuroscience. We model the WM damage in the notable case of Phineas P. Gage, in whom a "tamping iron" was accidentally shot through his skull and brain, resulting in profound behavioral changes. The specific effects of this injury on Mr. Gage's WM connectivity have not previously been considered in detail. Using computed tomography (CT) image data of the Gage skull in conjunction with modern anatomical MRI and diffusion imaging data obtained in contemporary right handed male subjects (aged 25-36), we computationally simulate the passage of the iron through the skull on the basis of reported and observed skull fiducial landmarks and assess the extent of cortical gray matter (GM) and WM damage. Specifically, we find that while considerable damage was, indeed, localized to the left frontal cortex, the impact on measures of network connectedness between directly affected and other brain areas was profound, widespread, and a probable contributor to both the reported acute as well as long-term behavioral changes. Yet, while significantly affecting several likely network hubs, damage to Mr. Gage's WM network may not have been more severe than expected from that of a similarly sized "average" brain lesion. These results provide new insight into the remarkable brain injury experienced by this noteworthy patient.     

Postradiation changes in the brain asymmetry and higher mental functions of right- and left-handed subjects (the sequelae of the accident at the Chernobyl Atomic Electric Power Station)

The present study was aimed at comparative electrophysiological, clinical, and neurophysiological assessment of the brain functional state in dextrals (50 men) and sinistrals (5 men), who participated in the Chernobyl clean. The patients were observed over the course of 10 years (from 1990 to 1999). The results of examination of healthy persons (20 dextrals and 10 sinistrals) were used as a control. The clinical examination revealed the earlier manifestation and more severe development of paroxysmal and epileptic seizures in sinistrals than in dextrals. Electrophysiological study showed a progressive decrease in interhemispheric asymmetry of the EEG coherence characteristic for a healthy brain to inversion of its sign. These changes were more pronounced in sinistrals. In the remote terms after radiation, the interhemispheric EEG coherence decreased over the whole cortex, especially, in the frontal and central areas in both groups of patients. Neurophysiological study revealed a progressive impairment of voluntary motor activity and tactile sensibility, especially, in the left hand. These defects were more expressed in sinistrals than in dextrals. The results of complex and longitudinal examination suggest that the observed changes in brain asymmetry and interhemispheric interaction can be not only a result of a dysfunction of subcortical limbic-reticular and mediobasal brain structures but also a result of the white matter damage including corpus callosum. More expressed impairments in sinistrals than in dextrals can be explained by specific morphofunctional organization of the brain in persons with different sensor and motor asymmetries.     

同种异体大鼠骨髓间充质干细胞移植对放射性空肠损伤的修复作用

目的观察同种异体骨髓间充质干细胞（MSCs）移植对放射性空肠的修复作用。方法全骨髓贴壁体外培养大鼠MSCs并进行DAPI标记。对大鼠行5 Gy X线全腹部照射,每隔72 h照射1次,共5次,制备放射性空肠损伤动物模型。取40只大鼠,随机分成正常对照组、模型及MSCs治疗组及DAP标记组。激光共聚焦显微镜下观察DAPI标记的MSCs在空肠组织中富集情况。病理学观察MSCs对放射性空肠损伤的修复作用。结果正常大鼠空肠黏膜结构清楚,隐窝深遂,腺体丰富,模型组7 d黏膜上皮细胞坏死脱落,隐窝几乎完全破坏,治疗组7 d黏膜坏死组织较少,黏膜增厚,30 d治疗组核分裂相增加,较模型组增加明显。结论成功建立放射性空肠损伤动物模型,MSCs可以促进空肠再生与修复。     

White matter injury following systemic endotoxemia or asphyxia in the fetal sheep

White matter injury is the most frequently observed brain lesion in preterm infants. The etiology remains unclear, however, both cerebral hypoperfusion and intrauterine infections have been suggested as risk factors. We compared the neuropathological outcome, including the effect on oligodendrocytes, astrocytes, and microglia, following either systemic asphyxia or endotoxemia in fetal sheep at midgestation. Fetal sheep were subjected to either 25 minutes of umbilical cord occlusion or systemic endotoxemia by administration of Escherichia coli lipopolysaccharide (LPS O111:B4, 100 ng/kg, IV). Periventricular white matter lesions were observed in 2 of 6 asphyxiated fetuses, whereas the remaining animals showed diffuse injury throughout the subcortical white matter and neuronal necrosis in subcortical regions, including the striatum and hippocampus. LPS-treatment resulted in focal inflammatory infiltrates and cystic lesions in periventricular white matter in 2 of 5 animals, but with no neuron specific injury. Both experimental paradigms resulted in microglia activation in the white matter, damaged astrocytes, and loss of oligodendrocytes. These results show that the white matter at midgestation is sensitive to injury following both systemic asphyxia and endotoxemia. Asphyxia induced lesions in both white and subcortical grey matter in association with microglia activation, and endotoxemia resulted in selective white matter damage and inflammation.     

Extracellular amino acids and lipid peroxidation products in periventricular white matter during and after cerebral ischemia in preterm fetal sheep

It is widely hypothesized that accumulation of excitatory amino acids, and oxygen free radicals during or after exposure to hypoxia–ischemia play a pivotal role in preterm periventricular white matter injury; however, there is limited evidence in the intact brain. In preterm fetal sheep (0.65 gestation; term 147 days) we found no significant increase in extracellular levels of excitatory amino acids measured by microdialysis in the periventricular white matter during cerebral ischemia induced by bilateral carotid occlusion. There was no significant change in 8-isoprostane or malondialdehyde levels in the early phase of recovery after occlusion. In contrast, there was a significant delayed increase in most amino acids and in malondialdehyde (but not 8-isoprostane) that was maximal approximately 2–3 days after occlusion. The increase in glutamate was significantly correlated with a secondary increase in cortical impedance, an index of cytotoxic edema, and with white matter damage 3 days post-insult. In conclusion, no significant accumulation of cytotoxins was found within immature white matter during cerebral ischemia. Although a minority of fetuses showed a delayed increase in some cytotoxins, this occurred many days after ischemia, in association with secondary cytotoxic edema, strongly suggesting that these changes are mainly a consequence of evolving cell death.