Functional roles of neuropeptides in the insect central nervous system

 With the completion of the Drosophila genome sequencing project we can begin to appreciate the extent of the complexity in the components involved in signal transfer and modulation in the nervous system of an animal with reasonably complex behavior. Of all the different classes of signaling substances utilized by the nervous system, the neuropeptides are the most diverse structurally and functionally. Thus peptidergic mechanisms of action in the central nervous system need to be analyzed in the context of the neuronal circuits in which they act and generalized traits cannot be established. By taking advantage of Drosophila molecular genetics and the presence of identifiable neurons, it has been possible to interfere with peptidergic signaling in small populations of central neurons and monitor the consequences on behavior. These studies and experiments on other insects with large identifiable neurons, permitting cellular analysis of signaling mechanisms, have outlined important principles for temporal and spatial action of neuropeptides in outputs of the circadian clock and in orchestrating molting behavior. Considering the large number of neuropeptides available in each insect species and their diverse distribution patterns, it is to be expected that different neuropeptides play roles in most aspects of insect physiology and behavior.     

Development of the vertebrate central nervous system: formation of the neural tube

The developmental process of neurulation involves a series of coordinated morphological events, which result in conversion of the flat neural plate into the neural tube, the primordium of the entire central nervous system (CNS). Failure of neurulation results in neural tube defects (NTDs), severe abnormalities of the CNS, which are among the commonest of congenital malformations in humans. In order to gain insight into the embryological basis of NTDs, such as spina bifida and anencephaly, it is necessary to understand the morphogenetic processes and molecular mechanisms underlying neural tube closure. The mouse is the most extensively studied mammalian experimental model for studies of neurulation, while considerable insight into underlying developmental mechanisms has also arisen from studies in other model systems, particularly birds and amphibians. We describe the process of neural tube formation, discuss the cellular mechanisms involved and highlight recent findings that provide links between molecular signaling pathways and morphogenetic tissue movements. Copyright © 2009 John Wiley & Sons, Ltd.     

Sonographic detection of central nervous system defects in the first trimester of pregnancy

The fetal central nervous system can already be examined in the first trimester of pregnancy. Acrania, alobar holoprosencephaly, cephaloceles, and spina bifida can confidently be diagnosed at that stage and should actively be looked for in every fetus undergoing first-trimester ultrasound. For some other conditions, such as vermian anomalies and agenesis of the corpus callosum, markers have been identified, but the diagnosis can only be confirmed in the second trimester of gestation. For these conditions, data on sensitivity and more importantly specificity and false positives are lacking, and one should therefore be aware not to falsely reassure or scare expecting parents based on first-trimester findings. This review summarizes the current knowledge of first-trimester neurosonography in the normal and abnormal fetus and gives an overview of which diseases can be diagnosed. © 2016 John Wiley & Sons, Ltd.     

Normal sonographic development of the central nervous system from the second trimester onwards using 2D, 3D and transvaginal sonography

The developmental changes of the fetal central nervous system (CNS) during the second and third trimesters, specifically the brain, relate mostly to changes in size. However, other changes do occur in the fetal brain during the second and third trimester such as: the union of the cerebellar hemispheres, development of the corpus callosum (CC), and increasing complexity of the cerebral cortex. These changes follow a well-defined developmental timeline recognizable by sonography. The fetal neuroscan can be divided into a ‘basic scan’ which is performed transabdominally and a ‘targeted Exam or neurosonogram’ which uses a multiplanar approach, which preferably should be performed transvaginally. During the ‘basic scan’, several brain structures are imaged in addition to obtaining important biometric measurements. The ‘neurosonogram’ is a more extensive or detailed fetal study during which the emphasis is on the addition of coronal and sagittal planes. The easiest way to obtain these planes, if the fetus is in a cephalic presentation, is the transvaginal route. Three-dimensional (3D) sonography should, if possible, be performed transvaginally using the multiplanar approach. An added benefit of 3D sonography is the ability to display and render the volume in a variety of ways which may enhance the detection of pathology. Copyright © 2008 John Wiley & Sons, Ltd.