Comprehensive Review of Ocular Angiostrongyliasis with Special Reference to Optic Neuritis

Angiostrongyliasis, caused by Angiostrongylus cantonensis infection, is a food-borne parasitic disease. Its larvae evoke eosinophilic inflammation in the central nervous system, but can also cause pathological changes in the eyes. Among ocular angiostrongyliasis cases, the incidence of optic neuritis is low and only few sporadic reports exist. Some patients with optic neuritis developed obvious hypopsia or even vision loss, which would seriously influence the quality of life of patients. Prompt treatment of optic neuritis caused by A. cantonensis is the key factor for minimizing the incidence of serious complications of this disease. In this review, we first provide a comprehensive overview of ocular angiostrongyliasis, and then focus on the clinical features of optic neuritis caused by A. cantonensis.     

Evidence for Tissue-Specific JAK/STAT Target Genes in Drosophila Optic Lobe Development

The evolutionarily conserved JAK/STAT pathway plays important roles in development and disease processes in humans. Although the signaling process has been well established, we know relatively little about what the relevant target genes are that mediate JAK/STAT activation during development. Here, we have used genome-wide microarrays to identify JAK/STAT targets in the optic lobes of the Drosophila brain and identified 47 genes that are positively regulated by JAK/STAT. About two-thirds of the genes encode proteins that have orthologs in humans. The STAT targets in the optic lobe appear to be different from the targets identified in other tissues, suggesting that JAK/STAT signaling may regulate different target genes in a tissue-specific manner. Functional analysis of Nop56, a cell-autonomous STAT target, revealed an essential role for this gene in the growth and proliferation of neuroepithelial stem cells in the optic lobe and an inhibitory role in lamina neurogenesis.     

MST3在颞叶癫痫模型小鼠海马的表达变化

目的观察海人酸(kainic acid,KA)所致癫痫(epilepsy,EP)小鼠海马Ste20蛋白激酵素(MST3)表达水平的变化,探讨MST3在癫痫发病过程中的可能作用。方法选用成年雄性小鼠,并随机分成模型组和对照组。模型组小鼠侧脑室注射2μL(100 ng/μL)KA,分别于术后3、8、24 h收集动物标本以进行检测。使用RT-PCR和Western Blot测定MST3 mRNA含量和MST3蛋白动态表达变化,应用免疫组化观察MST3在海马的表达分布与特点。结果与正常对照组相比,模型组海马组织内MST3mRNA的表达随时间持续升高,24 h达到高峰;MST3的蛋白表达也表现出同样的动态升高趋势;术后3～24 h的模型组海马免疫组化检测显示,模型组MST3主要以海马齿状回、门回区、CA3区域表达增加为主,并且这些区域表达逐渐递增。结论随着时间的推移,MST3表达水平呈现逐渐增加趋势,可能与神经元损伤造成的凋亡之间有密切的关系,提示MST3可能在癫痫发病过程中起重要作用。     

Suppression of the p75 receptor signal attenuates the effect of ephrin-B3 and promotes axonal regeneration of the injured optic nerve

The p75 neurotrophin receptor (p75NTR) is known to transduce the signal from some myelin-associated axon growth inhibitors, including Nogo and myelin-associated glycoprotein. As ephrin-B3, a member of the ephrin family, is also expressed in myelin and inhibits axon growth, the purpose of this study was to assess the possible involvement of p75NTR in ephrin-B3 signaling. Here, we report that p75NTR is required for the inhibitory effect of ephrin-B3 on neurite growth in vitro. While ephrin-B3 inhibited neurite elongation of embryonic cortical neurons, the neurons with p75NTR knockdown or with EphA4 knockdown were less sensitive to ephrin-B3. Although no direct interaction of p75NTR with ephrin-B3 was observed, Pep5, a peptide that specifically inhibits RhoA activation mediated by p75NTR, reduced the effect of ephrin-B3. Therefore, p75NTR functions as a signal transducer for ephrin-B3. Moreover, axonal regeneration in vivo was induced by Pep5 application after optic nerve crush injury in mice. Thus, Pep5 is a promising agent that contributes to axonal regeneration in the central nervous system.     

一种基于视网膜主血管方向的视盘定位及提取方法

为分割出眼底图像中的视盘,构建基于眼底图像的计算机辅助诊断系统,提出了一种基于视网膜主血管方向的视盘定位及提取方法。首先,利用Otsu阈值分割眼底图像R通道获取视盘候选区域;然后利用彩色眼底图像的HSV空间的H通道提取视网膜主血管并确定主血管方向;在此基础上,通过在方向图内寻找出对加权匹配滤波器响应值最高的点确定视盘中心位置;最后,利用该位置信息从视盘候选区域中"挑选"出真正的视盘。利用该方法对100幅不同颜色、不同亮度的眼底图像进行视盘分割,得到准确率98%,平均每幅图像处理时间1.3 s。结果表明:该方法稳定可靠,能快速、有效分割出眼底图像中的视盘。     

Nucleus Isthmi Is Required to Sustain Target Pursuit during Visually Guided Prey-Catching

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Raman ChemLighter: Fiber optic Raman probe imaging in combination with augmented chemical reality

Raman spectroscopy using fiber optic probe combines non‐contacted and label‐free molecular fingerprinting with high mechanical flexibility for biomedical, clinical and industrial applications. Inherently, fiber optic Raman probes provide information from a single point only, and the acquisition of images is not straightforward. For many applications, it is highly crucial to determine the molecular distribution and provide imaging information of the sample. Here, we propose an approach for Raman imaging using a handheld fiber optic probe, which is built around computer vision–based assessment of positional information and simultaneous acquisition of spectroscopic information. By combining this implementation with real‐time data processing and analysis, it is possible to create not only fiber‐based Raman imaging but also an augmented chemical reality image of the molecular distribution of the sample surface in real‐time. We experimentally demonstrated that using our approach, it is possible to determine and to distinguish borders of different bimolecular compounds in a short time. Because the method can be transferred to other optical probes and other spectroscopic techniques, it is expected that the implementation will have a large impact for clinical, biomedical and industrial applications.      

The role of mitochondria in sepsis-induced cardiomyopathy

Sepsis is defined as a life-threatening organ dysfunction caused by a dysregulated host response to infection. Myocardial dysfunction, often termed sepsis-induced cardiomyopathy, is a frequent complication and is associated with worse outcomes. Numerous mechanisms contribute to sepsis-induced cardiomyopathy and a growing body of evidence suggests that bioenergetic and metabolic derangements play a central role in its development; however, there are significant discrepancies in the literature, perhaps reflecting variability in the experimental models employed or in the host response to sepsis. The condition is characterised by lack of significant cell death, normal tissue oxygen levels and, in survivors, reversibility of organ dysfunction. The functional changes observed in cardiac tissue may represent an adaptive response to prolonged stress that limits cell death, improving the potential for recovery. In this review, we describe our current understanding of the pathophysiology underlying myocardial dysfunction in sepsis, with a focus on disrupted mitochondrial processes.     

Wie V?gel ihr Auge schützen: Zur Arbeitsteilung von Oberlid, Unterlid und Nickhaut

Zusammenfassung Vögel schließen ihre Augen im Schlaf in einer für die großen Taxa typischen Weise. Entweder geht das Unterlid hoch wie bei der Mehrzahl der Arten, oder das Oberlid bewegt sich abwärts (Psittaciformes, Trochili), oder aber beide Lider schließen die Lidspalte (Strigiformes, Caprimulgi). Solche Kenntnis fehlt von den meisten Ordnungen, oder die Handbücher geben falsche oder widersprüchliche Information. Neben dem tonischen, schlafbegleitenden Augenschluss bewegen Vögel im Wachzustand eines oder beide Lider phasisch und meist schnell. Dieser häufige Lidschlag ist durch ein anderes Bewegungsmuster und durch eine andere Funktion gekennzeichnet. Photodokumente und genaue Beobachtungen führen erstmals zu einer funktionellen Deutung, der zufolge der Lidschlag das Auge mechanisch schützt. Droht dem Auge von vorn oder von oben eine potentielle Schädigung, so schließt das Oberlid bei Tauben, Eulen und Singvögeln, im Sprühwasser gleichzeitig auch das Unterlid (Cinclus). Der unabweisbarste Beleg stammt aus dem Vergleich des Aufpickens dorniger, sperriger Beuteinsekten mit Oberlidschluss gegenüber dem Aufnehmen harmloser Beeren ohne jede Lidbewegung (Gallicolumba). Weiter ist die Antwort des Oberlids, anders als beim Unterlid, öfter seitengerecht reizorientiert, so dass die Bewegung einseitig sein kann. Zudem kann der Schluss des Oberlids auch bei stationärem (Feind-)reiz seitenweise alternieren (Otus). Ausnahmsweise tritt eine adaptive Asymmetrie auch während kurzer Zeiten der Augenöffnung zum Spähen nach Feinden im Schlaf auf, und zwar hier beim Unterlid der bedrohten Seite (Anas).Eine neue Funktion wird auch dem Schlag der Nickhaut (Membrana nictitans) zugeschrieben. Traditionell als die Cornea reinhaltendes Organ gesehen, dient auch sie dem mechanischen Schutz des Auges. Auch sie kann seitenrichtig reizorientiert schlagen, doch ist hierüber wenig bekannt. Dieselben Reize, die den Lidschlag auslösen, können bei anderen Arten die Nickhaut schlagen lassen. Ihre Schlagrate ist schwierig zu messen, da viele Schläge (nur?) mit denen des Oberlides zusammenfallen und so verborgen bleiben (Otus). Diese Synchronie ist mit keiner der bisher vorgeschlagenen Funktionen erklärbar, ebenso wenig wie die verborgenen Schläge bei tonischem Augenschluss (Passer).Die Annahme einer Ausschaltung störender Sinnesinformation, z.B. während rascher Kopfbewegungen, durch die Nickhaut lässt sich aus vier Gründen verwerfen. Die Zunahme der Schlagrate während des Feindalarms (Ficedula) bleibt funktionell unerklärt.In einer bei Vögeln einzigartigen Weise schützt der Samtkleiber (Sitta azurea) sein Auge durch Zusammenziehen des nackten Augenrings (Lidblende), wenn er rücklings an der Unterseite von Ästen nahrungssuchend einem ständigen Regen von losgelösten Rindenteilchen u. ä. ausgesetzt ist.Sekundär haben sich die Bewegungen eines oder beider Lider oder aber der Nickhaut zu optischen Signalen entwickelt, und zwar durch kontrastierende Feder- oder Nickhautfärbung. Die betreffenden blitzschnell aufleuchtenden Signale sind an den Paarpartner (Cinclus, Corvidae,Cepphus), an mögliche Feinde (Anas) oder an bisher unbekannte Empfänger gesichtet (Ficedula).

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On how birds protect their eyes: division of labour between the upper lid, lower lid and the nictitating membrane

Summary Birds close their eyes during sleep in various taxon-specific ways. Either the lower lid moves up as in the majority of species including the Anseres, Accipitres, Falconiformes, Galli, Charadrioidea, Columbiformes, and Oscines; or the upper lid moves down (Psittaciformes, Trochili), or both lids close the eye as in Strigiformes and Caprimulgi. Such information is absent for most orders, or the handbooks provide wrong or conflicting information. Beside the tonic, sleep-related eye closure, birds move one or both lids in a phasic, usually swift mode when awake. These frequent lid movements are typified by their different co-ordination and function. Photographic and observational evidence strongly suggests mechanical protection of the eye as a novel function (where this had not been proposed previously). When an impact from any object is imminent from in front of or above the head, the upper lid shuts in pigeons, owls and oscines, and with water splashing, the lower lid as well (Cinclus). The most convincing evidence for mechanical protection comes from the deployment of the upper lid during the picking up of spiny insect prey as compared to easy-to-swallow berries, when both lids stay at rest (Gallicolumba).Further, the response of the upper lid is more stimulus-oriented so that both upper lids move asymmetrically. But there is also a unilateral, alternating winking of the upper lids when causative (predator) stimuli remain stationary. This never occurs with the lower lids (Otus). As an exception, an adaptive asymmetry occurs during brief phases of unilateral scanning interrupting sleep, designed to detect approaching predators. This scanning involves the lower lid (Anas).A new function is also attributed to the beating of the nictitating membrane (Membrana nictitans). Traditionally viewed as a cleaning device it also serves to protect the eye from mechanical impact, and it also can be tuned to the side from where danger is threatening, though by and large there is a dearth of information from avian taxa. The non-visually elicited action of the membrane seems always to be bilateral (Falco, Harpia). The very stimuli eliciting the blinking of a lid can, in different species, trigger the beat of the membrane, and can cause it to move tonically (Falco). The membrane beats at a rate difficult to measure since many of its beats coincide with the blinking of the upper lid and thus remain hidden (Otus). This coincidence is difficult to account for by any function discussed so far, as are the many hidden beats during tonic eye closure with the lids (Passer).The hypothesis according to which the action of the membrane is filtering out undesirable retinal stimulation during e.g. rapid head movements is dismissed on four different grounds. The increase of the membrane activity during predator alarm (Ficedula) is functionally unaccounted for.In a fashion unique among birds, the Blue Nuthatch (Sitta azurea) protects its eyes by contracting the naked skin surrounding the eye, thereby minimizing the exposure of the cornea; during foraging along the underside of branches, a continual rain of bark particles and debris jeopardizes unimpeded vision.Secondarily, one or both lids or the nictitating membrane have taken on the function of optic signals by virtue of contrasting feather colour or coloration. The phasic (flashing) signal movements involved are directed at the pair mate (Cinclus, Corvidae,Cepphus), predators (Anas) or at unknown parties (Ficedula).

Dies ist Veröffentlichung Nr. 29 des Philippine Endemic Species Conservation Project der Zoologischen Gesellschaft Frankfurt.     

Possible roles of beta-catenin in evagination of the optic primordium in rat embryos

The roles of beta-catenin in evagination of the optic primordium in rat embryos were studied using immunostaining. High levels of beta-catenin appeared transiently in the evaginating optic primordium. Evagination of the optic primordium was suppressed in embryos treated with LiCl. In deficient optic vesicles of these embryos, accumulation of beta-catenin was decreased. Deficient optic vesicles also showed suppression of cyclin D1 accumulation and bromodeoxyuridine incorporation, no break in the deposition of laminin and type IV collagen at the basement membrane (BM) and prevention of the change in distribution of microtubules and microfilaments. These results suggest that beta-catenin regulates cell proliferation, breakdown of BM and changes in cell shape in the evaginating optic primordium to cause optic vesicle formation.