Doxapram accentuates white matter injury in neonatal rats following bilateral carotid artery occlusion

The effect of the respiratory stimulant, doxapram, on white matter damage was investigated in neonatal rats under cerebral ischemia. Five-day-old rats underwent bilateral carotid artery occlusion with or without 50 mg/kg i.p. of doxapram. Their brains were neuropathologically examined 48 h later. Doxapram induced about a 20% decrease of PCO(2) for 90 min, but did not cause any neuropathological abnormalities. Bilateral carotid artery occlusion resulted in mild cerebrocortical lesions in 67% of pups, and white matter lesions in the internal capsule in 44%. Doxapram, in addition to bilateral carotid artery occlusion, produced more severe white matter injury in the internal capsule (injury score; 0.67+/-0.87 vs. 1.70+/-0.48, P<0.05) and in the subcortical white matter (0.33+/-0. 67 vs. 1.10+/-0.54, P<0.05). These results demonstrated that the use of doxapram under an ischemic condition accentuates white matter damage in neonatal rats.     

Delayed white matter injury in a murine model of shaken baby syndrome

Shaken baby syndrome, a rotational acceleration injury, is most common between 3 and 6 months of age and causes death in about 10 to 40% of cases and permanent neurological abnormalities in survivors. We developed a mouse model of shaken baby syndrome to investigate the pathophysiological mechanisms underlying the brain damage. Eight-day-old mouse pups were shaken for 15 seconds on a rotating shaker. Animals were sacrificed at different ages after shaking and brains were processed for histology. In 31-day-old pups, mortality was 27%, and 75% of survivors had focal brain lesions consisting of hemorrhagic or cystic lesions of the periventricular white matter, corpus callosum, and brainstem and cerebellar white matter. Hemorrhagic lesions were evident from postnatal day 13, and cysts developed gradually between days 15 and 31. All shaken animals, with or without focal lesions, had thinning of the hemispheric white matter, which was significant on day 31 but not earlier. Fragmented DNA labeling revealed a significant increase in cell death in the periventricular white matter, on days 9 and 13. White matter damage was reduced by pre-treatment with the NMDA receptor antagonist MK-801. This study showed that shaking immature mice produced white matter injury mimicking several aspects of human shaken baby syndrome and provided evidence that excess release of glutamate plays a role in the pathophysiology of the lesions.     

Diffuse axonal injury in early infancy.

Diffuse axonal injury typified by retraction balls and axonal swellings was identified in the brains of a series of infants, 5 months old and younger, who had suffered closed head injuries. These axonal discontinuities were shown by using Nauomenko and Feigin's silver method, which is particularly useful for showing fine axons such as those found in the developing brain. Diffuse axonal injury in early infancy may occur in the same way as that described in adults. The low incidence of intracerebral haematomata suggests that recurrent trauma to the head from a combination of direct contact and shaking results in axonal damage to the poorly myelinated axons and that blood vessels are rarely damaged.     

Extracellular glutamate levels and neuropathology in cerebral white matter following repeated umbilical cord occlusion in the near term fetal sheep

Umbilical cord occlusion causes fetal hypoxemia which can result in brain injury including damage to cerebral white matter. Excessive glutamate release may be involved in the damage process. This study examined the relation between extracellular glutamate levels in the cerebral white matter of the ovine fetus during and after intermittent umbilical cord occlusion and the degree of resultant fetal brain injury. Fetal sheep underwent surgery for chronic catheterisation and implantation of an intra-cerebral microdialysis probe at 130 days of gestation (term approximately 147 days). Four days after surgery (day 1), seven fetuses were subjected to 5x2 min umbilical cord occlusions, and on the following day (day 2) they were subjected to either 4 or 5x4 min umbilical cord occlusions; seven fetuses served as controls. Microdialysis samples were collected before, during and after the umbilical cord occlusions to determine extracellular glutamate levels in the cerebral white matter. Fetal blood gas status was measured and the fetal electrocorticogram was recorded continuously. During the periods of umbilical cord occlusions on both days 1 and 2, fetal arterial oxygen saturation, arterial partial pressure of oxygen and arterial pH decreased (P<0.05) while arterial partial pressure of carbon dioxide increased (P<0.05). All fetuses showed episodes of isoelectric electrocortical activity during umbilical cord occlusions on both days 1 and 2. In fetuses with patent microdialysis probes there were marked increases of glutamate efflux in the cerebral white matter following umbilical cord occlusion. Fetal brains were removed at autopsy on day 5 and subjected to histological assessment. Brain damage was observed in all fetuses exposed to cord occlusion, particularly in the periventricular white matter, with the most extensive damage occurring in the fetuses with the greatest increases in glutamate levels. We conclude that, in the unanesthetised fetus in utero, glutamatergic processes are associated with umbilical cord occlusion-induced brain damage in the cerebral white matter.     

Alpha-Phenyl-n-tert-butyl-nitrone attenuates lipopolysaccharide-induced neuronal injury in the neonatal rat brain

Although white matter damage is a fundamental neuropathological feature of periventricular leukomalacia (PVL), the motor and cognitive deficits observed later in infants with PVL indicate the possible involvement of cerebral neuronal dysfunction. Using a previously developed rat model of white matter injury induced by cerebral lipopolysaccharide (LPS) injection, we investigated whether LPS exposure also results in neuronal injury in the neonatal brain and whether alpha-phenyl-n-tert-butyl-nitrone (PBN), an antioxidant, offers protection against LPS-induced neuronal injury. A stereotactic intracerebral injection of LPS (1 mg/kg) was performed in Sprague-Dawley rats (postnatal day 5) and control rats were injected with sterile saline. LPS exposure resulted in axonal and neuronal injury in the cerebral cortex as indicated by elevated expression of beta-amyloid precursor protein, altered axonal length and width, and increased size of cortical neuronal nuclei. LPS exposure also caused loss of tyrosine hydroxylase positive neurons in the substantia nigra and the ventral tegmental areas of the rat brain. Treatments with PBN (100 mg/kg) significantly reduced LPS-induced neuronal and axonal damage. The protection of PBN was associated with an attenuation of oxidative stress induced by LPS as indicated by the reduced number of 4-hydroxynonenal, malondialdehyde or nitrotyrosine positive cells in the cortical area following LPS exposure, and with the reduction in microglial activation stimulated by LPS. The finding that an inflammatory environment may cause both white matter and neuronal injury in the neonatal brain supports the possible anatomical correlate for the intellectual deficits and the other cortical and deep gray neuronal dysfunctions associated with PVL. The protection of PBN may indicate the potential usefulness of antioxidants for treatment of these neuronal dysfunctions.     

Age‐Associated White Matter Lesions: The MRC Cognitive Function and Ageing Study

Cerebral white matter lesions (WML) are common in the aging brain and are associated with dementia and depression. They are associated with vascular risk factors and small vessel disease, suggesting an ischemic origin, but recent pathology studies suggest a more complex pathogenesis. Studies using samples from the population‐representative Medical Research Council Cognitive Function and Ageing Study neuropathology cohort used post‐mortem magnetic resonance imaging to identify WML for further study. Expression of hypoxia‐related molecules and other injury and protective cellular pathways in candidate immunohistochemical and gene expression microarray studies support a role for hypoxia/ischemia. However, these approaches also suggest that immune activation, blood–brain barrier dysfunction, altered cell metabolic pathways and glial cell injury contribute to pathogenesis. These abnormalities are not confined to WML, but are also found in apparently normal white matter in brains with lesions, suggesting a field effect of white matter abnormality within which lesions arise. WML are an active pathology with a complex pathogenesis that may potentially offer a number of primary and secondary intervention targets.     

Development of spontaneous leg movements in infants with and without periventricular leukomalacia

The main question asked in the present study was whether support could be found for the notion that supraspinal influences on the generation of spontaneous kicking movements become increasingly apparent in the first half-year after birth. In comparing groups of infants with and without damage in tracts connected with the cortex surrounding the central sulcus, such support would consist of the finding that similar patterns of spontaneous kicking are observed early in development, whereas differences between groups should occur with increasing age. Using 3-D registrations, the spontaneous kicking movements of 19 infants with differing degrees of periventricular, lobar, and subcortical leukomalacia based on white matter (WM) abnormalities on ultrasound were compared to those of 10 healthy control infants at 6, 12, 18, and 26 weeks of corrected age. Magnetic resonance imaging recordings were used to identify the location and severity of the brain lesions. Infants with extensive lesions in the periventricular and lobar WM with or without diffuse lesions in the subcortical WM showed a decreased variability on some spatial and temporal parameters of kicks. More importantly, these infants showed a different developmental course for intralimb couplings when compared to the other infants; they were unable to dissociate tight intralimb couplings at 18 and 26 weeks. As all of these infants had substantial damage of the corticospinal tracts, these findings suggest that these tracts are involved in the regulation of intralimb joint dissociations between 4 and 6 months of age. However, caution is needed as areas outside those in which the corticospinal tracts are located could be damaged as well and most of the infants with moderate to severe lesions in the corticospinal tract had additional psychomotor problems. For interlimb couplings and most of the spatial and temporal parameters of kicks, no differences were found between groups. This strengthens the claim that inter- and intralimb couplings are organized in fundamentally different ways.     

Optic nerve damage in shaken baby syndrome: detection by beta-amyloid precursor protein immunohistochemistry

BACKGROUND: Rapid acceleration-deceleration of an infant's head during intentional shaking should in theory exert stretch or shear forces upon the optic nerves sufficient to cause axonal injury. beta-Amyloid precursor protein (beta-APP) immunohistochemistry recently has been shown to be a highly effective method for identifying diffuse axonal injury in the brains of infants with shaken baby syndrome. In this study, we investigated the utility of beta-APP in identifying optic nerve damage in infants who have sustained fatal whiplash shaking. MATERIALS AND METHODS: beta-Amyloid precursor protein immunohistochemistry was performed on formalin-fixed, paraffin-embedded sections of eyes (including optic disc and distal optic nerve) from infants less than 1 year of age with shaken baby syndrome (5 cases), combined shaken baby syndrome/blunt head trauma (3 cases), and "pure" blunt head trauma (1 case). Nontraumatic control cases included infants who died of suffocation (1 case), sudden infant death syndrome (1 case), and positional asphyxia (1 case) and an enucleation from a child with a retinoblastoma (1 case). Matched hematoxylin-eosin-and neurofilament-stained sections were used for comparison. RESULTS: Three of the 5 shaken baby cases and all 3 combined shaken baby/blunt head trauma cases had optic nerve axonal injury identified by the presence of strongly beta-APP-immunoreactive beaded or swollen axonal segments. Axonal injury could not be detected in the corresponding hematoxylin-eosin-or neurofilament-stained sections. Optic nerve axonal injury was not seen in the case involving pure blunt head trauma or in the nontraumatic control cases. CONCLUSIONS: Optic nerve axonal injury is a prominent feature of intentional fatal whiplash head trauma in infants less than 1 year of age. beta-Amyloid protein precursor immunohistochemistry appears to be the most effective method for demonstrating axonal damage in the optic nerve.     

Gliding contusions in nonmissile head injury in humans

"Gliding" contusions, ie, hemorrhagic lesions in the parasagittal white matter, were analyzed in 434 fatal nonmissile head injuries in humans. It is concluded that gliding contusions are a type of diffuse brain damage occurring at the moment of injury. Gliding contusions are significantly associated with road-traffic accidents, with the absence of a skull fracture or a "lucid interval," and with the presence of diffuse axonal injury and deep hemispheric traumatic hematomas.     

Why do histology on retinal haemorrhages in suspected non‐accidental injury?

The detailed documentation of ocular pathology has become an important component in the autopsy investigation of suspected cases of non-accidental injury in infants and young children. Careful histological examination of retinal haemorrhages is of critical importance, but there remains debate about the significance of some findings. This issue has been thrown into sharper relief by recent neuropathological studies questioning the mechanisms of some CNS findings. To discuss the importance of histological findings in the retina and their potential significance and specificity, we have invited contributions from authors in the USA and UK.     

高危晚期早产儿脑损伤病因学及其磁共振发现

目的探讨以弥散加权成像（DWI）结合常规磁共振成像（T1WI-T2WI）诊断的高危晚期早产儿脑损伤的相关危险因素及临床特点,并分析不同时间MRI序列的信号特点及DWI的早期诊断价值。方法首先对符合纳入标准的649例晚期早产儿的MRI片重新阅片,按照脑损伤评估标准得出诊断,其次收集相关的临床资料,分析不同类型脑损伤的危险因素和临床特点,并对其中271例确诊脑白质损伤（CWMD）的MRI序列进行分析,探讨不同类型CWMD的信号特点、损伤部位及结局。结果①晚期早产儿发生脑损伤332例（51．2％）,其中CWMD271例（41．8％）,以局灶性CWMD为主（62．7％,170例）;颅内出血112例（17．3％）,主要为蛛网膜下腔出血55．4％（62／112）。②非出血性脑损伤的危险因素是男性（OR=1．510,95％CI：1．067～2．136,P=0．020）、阴道分娩（OR：2．367,95％CI：0．251～22．294,P=0．000）、早发型败血症（OR=2．194,95％CI：1．159—4．155,P=0．016）及抢救复苏史（OR=3．784,95％CI：1．908～7．506,P：0．000）。出血性脑损伤的危险因素是阴道分娩（OR=7．195,95％CI：4．249～t2．184,P=0．000）和早发型败血症（OR：2．692,95％CI：1．185～6．117,P=0．018）。低钙血症（OR=2．593,95％CI：1．343—5．005,P=0．005）、晚发型败血症（OR=1．533,95％CI：1．012～2．323,P=0．044）和抽搐（OR=4．006,95％CI：1．790—8．970,P=0．001）是非出血性脑损伤组的主要临床特点。出血性脑损伤组主要表现为高血糖和抽搐。③局灶性CWMD65．3％仅累及一处损伤,主要集中在侧脑室后脚（53．5％）,有97．1％病灶消失或病灶范围减少;广泛性CWMD79．2％累及胼胝体和内囊;弥漫性CWMD50％合并灰质损伤,全部发生软化。④生后2周内,DWI具有较高的敏感性,98．0％表现为高信号,T1WI信号无变化或稍高信号,伴或不伴T2WI低信号。局灶性CWMDDWI高信号持续时间长达5周以上,弥漫性CWMDDWI高信号持续时间2周以内。结论晚期早产儿仍然容易受产前产时因素影响而发生不同类型的脑损伤。对有高危因素,或早期出现临床表现或电解质紊乱的患儿应选择生后2周内（1周内最佳）进行DWI和常规MRI检查,以早期发现病变。局灶性CWMD预后较好,合并有灰质损伤或弥漫性CWMD预后极差,需要动态随访,并进行早期康复训练。     

Signature tau neuropathology in gray and white matter of corticobasal degeneration

Corticobasal degeneration (CBD) is an adult-onset progressive neurodegenerative disorder characterized by L-dopa-resistant rigidity, focal cortical deficits, and variable dementia. The neuropathological hallmark of CBD is the deposition of filamentous inclusions in neurons and glia composed of hyperphosphorylated tau with only four microtubule-binding repeats (4R-tau). To characterize the regional burden of tau pathology in CBD, we studied 12 brains with the neuropathological diagnosis of CBD using biochemical and histochemical techniques. Eleven brain regions were evaluated including gray and white matter from frontal, parietal, temporal, and occipital lobes and cerebellum as well as basal ganglia. Although the distribution of tau pathology was variable, neuropathological and biochemical data showed a similar burden of tau abnormalities in frontal, temporal, and parietal lobes and basal ganglia of both hemispheres. This included abundant, sarkosyl-insoluble 4R-tau in both gray and white matter of two or more of these cortical regions and basal ganglia, and to a lesser extent, cerebellar white matter. The insoluble tau pathology in gray and white matter showed overlapping but distinct phosphorylated epitopes suggesting cell-type and subcellular localization (ie, cell bodies versus cell processes)-specific differences in tau phosphorylation. In contrast, soluble tau was composed of normal 4R/3R-tau ratios indicating no gross abnormality in tau splicing. Thus, although clinically heterogeneous, CBD is a distinct lobar and basal ganglionic tauopathy with selective aggregation of 4R-tau.     

Intracranial diffuse axonal injury at autopsy

An illustrative case of diffuse axonal injury (DAI) emphasizes features that help to separate focal outer head trauma owing to blows and/or falls from angular acceleration head injuries associated with diffuse inner brain lesions. In the past, explaining significant neurological deficits and death as the result of diffuse closed head trauma received from high-speed automobile accidents has been difficult as well as confusing. The long-term consequences from such diffuse inner cerebral trauma are still poorly defined. Head injuries sustained in automobile accidents have been associated with diffuse brain damage characterized by axonal injury at the moment of impact. The reported victim of a motor vehicle accident showed post-mortem findings for both inner cerebral trauma and focal outer cerebral damage. The diffuse degeneration of cerebral white matter is associated with sagittal and lateral acceleration with centroaxial trauma and has a different pathogenesis from outer focal head trauma, typified by subdural hematomas and coup injuries. Unlike outer cerebral injury, over 50 percent of victims with diffuse axonal injury die within two weeks. These individuals characteristically have no lucid interval and remain unconscious, vegetative, or severely disabled until death. Compared to head trauma victims without diffuse axonal injury, there is a lower incidence of skull fractures, subdural hemorrhages, or other intracranial mass effect as well as outer brain contusions. Primary brainstem injuries often demonstrated at autopsy are seen in the reported victim. Diffuse axonal injury is produced by various angles of acceleration with prolonged acceleration/deceleration usually accompanying traffic accidents. Less severe diffuse axonal injury causes concussion.     

Central role of microglia in neonatal excitotoxic lesions of the murine periventricular white matter

Periventricular leukomalacia (PVL) is the main cause of neurologic handicap in pre-term infants. The understanding of cellular and molecular mechanisms leading to white matter damage is critical for development of innovative therapeutic strategies for PVL.The pathogenesis of PVL remains unclear but possibly involves glutamate excitotoxicity as an important molecular pathway. We previously described a neonatal mouse model of excitotoxic white matter lesion mimicking human PVL. In the present study, we used this experimental tool to investigate the cellular populations and the glutamate receptor subtypes involved in excitotoxic white matter lesions. Combined immunohistochemical, electron microscopic, and cell death detection data revealed that microglial activation and astrocytic death were the primary responses of white matter to excitotoxic insult. In vitro experiments suggested that microglia activated by ibotenate released soluble factors that kill astrocytes. The use of selective agonists and antagonists of glutamate receptors revealed that N-methyl-D-aspartate (NMDA) receptor activation was essential and sufficient to produce cystic white matter lesions. NMDA receptor immunohistochemistry labeled microglial cells in the neonatal periventricular white matter. The developing white matter displayed a window of sensitivity to excitotoxic damage that was paralleled by the transient presence of NMDA receptor-expressing white matter cells. Assuming that similar pathophysiologic mechanisms are present in human pre- term infants, microglia and NMDA receptors could represent key targets for treatment of PVL.     

The pathogenesis of neonatal post-hemorrhagic hydrocephalus

Hydrocephalus after intraventricular hemorrhage (IVH) has emerged as a major complication of preterm birth and is especially problematic to treat. The hydrocephalus is usually ascribed to fibrosing arachnoiditis, meningeal fibrosis and subependymal gliosis, which impair flow and resorption of cerebrospinal fluid (CSF). Recent experimental studies have suggested that acute parenchymal compression and ischemic damage, and increased parenchymal and perivascular deposition of extracellular matrix proteins--probably due at least partly to upregulation of transforming growth factor-beta (TGF-beta)--are further important contributors to the development of the hydrocephalus. IVH is associated with damage to periventricular white matter and the damage is exacerbated by the development of hydrocephalus; combinations of pressure, distortion, ischaemia, inflammation, and free radical-mediated injury are probably responsible. The damage to white matter accounts for the high frequency of cerebral palsy in this group of infants. The identification of mechanisms and mediators of hydrocephalus and white matter damage is leading to the development of new treatments to prevent permanent hydrocephalus and its neurological complications, and to avoid shunt dependence.     

Morphologic Variations in Periventricular Leukomalacia

Periventricular leukomalacia (PVL) usually is manifested as discrete foci of coagulation necrosis of the deep periventricular white matter in the human neonatal brain. During the examination of the brains of 116 infants utilizing an oil red O technic on gelatin-embedded frozen sections, 25 cases of PVL were found with typical foci of coagultion necrosis. Three morphologic varieties of the lesion could be demonstrated. In the first type, rather than being restricted to the periventricular zone, the discrete necrotic foci extended throughout the entire zone of cerebral white matter, even out to just beneath the cortex. The subcortical lesions appeared of short duration, whereas older lesions were always present nearer the ventricle. The second type of lesion presented as linear, some-what serpentine zones of coagulation necrosis radiating into the cerebral white matter. A third type of lesion consisted of a variegated irregular coagulation necrosis which was poorly delineated from more normal tissue. Diffuse pallor of the white matter, the nature of which is still not clear, was associted with the more severe lesions. Although the pathogenesis of PVL is unknown, it is suggested that these new varieties of PVL beyond the discrete periventricular foci of necrosis would be more apt to result in a diffuse loss of white matter and hence mental retardation if the child should survive.     

Time-dependent increase in Nogo-A expression after focal cerebral ischemia in marmoset monkeys

Nogo-A is a myelin-associated protein that has been shown to inhibit axonal sprouting after lesions to the CNS. Several studies have demonstrated that blocking the activity or expression of this inhibitor can induce structural and functional recovery after CNS lesions. However, there are limited and contradictory data on the expression of Nogo-A after CNS lesions. In the present study, marmoset monkeys received permanent occlusion of the middle cerebral artery (MCAo). Two, 3, or 4 months after the onset of injury brain sections were stained for Nogo-A protein. Two sham operated marmosets were included as a control. Nogo-A protein expression was quantified in white matter and grey matter in the areas adjacent to the lesion (or the equivalent areas in the intact side). At 2 months after injury, but not at 3 or 4 months, there was a significant increase in the number of oligodendrocytes that were Nogo-A immunopositive. This increase was observed in white matter structures that were adjacent to the lesion (e.g. corona radiate (CR)); but not in: white matter structures distal to the lesion (e.g. corpus callosum (CC)); cortical regions adjacent to the lesion; contralateral regions or in sham operated marmosets. These data suggest that Nogo-A levels are significantly increased within oligodendrocytes in areas adjacent to the lesion up to 2 months following cerebral ischaemia. Future studies will determine whether this offers the opportunity to promote plasticity by targeting Nogo-A weeks or months following stroke.     

Deleterious effects of plasminogen activators in neonatal cerebral hypoxia-ischemia

The immature brains of newborns often respond differently from the brains of adults when exposed to similar insults. Previous studies have indicated that although hypoxia-ischemia (HI) induces persistent thrombosis in adult brains, it only modestly impairs blood perfusion in newborn brains. Here, we used the Vannucci model of HI encephalopathy to study age-related responses to cerebral HI in rat pups. We found that HI triggered fibrin deposition and impaired blood perfusion in both neonatal and adult brains. However, these effects were only transient in neonatal brains (<4 hours) and were accompanied by acute induction of both tissue-type and urinary-type plasminogen activators (tPA and uPA), which was not observed in adult brains subjected to the same insult. Interestingly, activation of the plasminogen system persisted up to 24 hours in neonatal brains, long after the clearance of fibrin-rich thrombi. Furthermore, astrocytes and macrophages outside blood vessels expressed tPA after HI, suggesting the possibility of tPA/plasmin-mediated cytotoxicity. Consistent with this hypothesis, injection of alpha2-antiplasmin into cerebral ventricles markedly ameliorated HI-induced damage to neurofilaments and white matter oligodendrocytes, providing a dose-response reduction of brain injury after 7 days of recovery. Conversely, ventricular injection of tPA increased HI-induced brain damage. Together, these results suggest that tPA/plasmin induction, which may contribute to acute fibrinolysis, is a critical component of extravascular proteolytic damage in immature brains, representing a new therapeutic target for the treatment of HI encephalopathy.