Engraftable neural crest stem cells derived from cynomolgus monkey embryonic stem cells

Neural crest stem cells (NCSCs), a population of multipotent cells that migrate extensively and give rise to diverse derivatives, including peripheral and enteric neurons and glia, craniofacial cartilage and bone, melanocytes and smooth muscle, have great potential for regenerative medicine. Non-human primates provide optimal models for the development of stem cell therapies. Here, we describe the first derivation of NCSCs from cynomolgus monkey embryonic stem cells (CmESCs) at the neural rosette stage. CmESC-derived neurospheres replated on polyornithine/laminin-coated dishes migrated onto the substrate and showed characteristic expression of NCSC markers, including Sox10, AP2α, Slug, Nestin, p75, and HNK1. CmNCSCs were capable of propagating in an undifferentiated state in vitro as adherent or suspension cultures, and could be subsequently induced to differentiate towards peripheral nervous system lineages (peripheral sympathetic neurons, sensory neurons, and Schwann cells) and mesenchymal lineages (osteoblasts, adipocytes, chondrocytes, and smooth muscle cells). CmNCSCs transplanted into developing chick embryos or fetal brains of cynomolgus macaques survived, migrated, and differentiated into progeny consistent with a neural crest identity. Our studies demonstrate that CmNCSCs offer a new tool for investigating neural crest development and neural crest-associated human disease and suggest that this non-human primate model may facilitate tissue engineering and regenerative medicine efforts.     

A comparison between fibula and iliac crest in mandibular reconstruction

Nowadays the vascularized free fibula flap and the free iliac crest flap are the methods most frequently used to reconstruct the mandible. This is also the case in our clinic. A retrospective nonrandomized study was performed to compare both flaps. The vascularized fibula free flap and the iliac crest free flap were compared in terms of logistics, flap failure, revisionary surgery, donor site morbidity, and recipient site morbidity. No significant differences in flap failure and revision surgery were found between the fibula group and the iliac crest group. Recipient site and donor site complications (major and minor) were significantly less in the fibula group compared to the iliac crest group. In mandibular reconstruction, the free vascularized fibula flap appears to be superior to the free vascularized iliac crest flap in terms of both recipient site and donor site morbidity.     

基于虚拟仪器技术的高频电刀波峰因子检测与验证

提出了一种有效易行的高频电刀波峰因子检测系统的软、硬件设计方案。利用电磁感应原理接收电刀输出波形,由普通的数字示波器完成数据采集与数字化,基于虚拟仪器技术的PC端软件根据数据计算波峰因子。通过对高频电刀波峰因子的检测,最终验证波峰因子对电刀性能以及临床使用效果的重要性。     

Role of the extracellular matrix in neural crest cell migration

Development of the neural crest involves a remarkable feat of coordinated cell migration in which cells detach from the neural tube, take varying routes of migration through the embryonic tissues and then differentiate at the end of their journey to participate in the formation of a number of organ systems. In general, neural crest cells appear to migrate without the guidance of long-range physical or chemical cues, but rather they respond to heterogeneity in the extracellular matrix that forms their migration substrate. Molecules such as fibronectin and laminin act as permissive substrate components, encouraging neural crest cell attachment and spreading, whereas chondroitin sulphate proteoglycans are nonpermissive for migration. A balance between permissive and nonpermissive substrate components seems to be necessary to ensure successful migration, as indicated by a number of studies in mouse mutant systems where nonpermissive molecules are over-expressed, leading to inhibition of neural crest migration. The neural crest expresses cell surface receptors that permit interaction with the extracellular matrix and may also modify the matrix by secretion of proteases. Thus the principles that govern the complex migration of neural crest cells are beginning to emerge.     

Genetic screen for mutations affecting development and function of the enteric nervous system.

An intact enteric nervous system is required for normal gastrointestinal tract function. Several human conditions result from decreased innervation by enteric neurons; however, the genetic basis of enteric nervous system development and function is incompletely understood. In an effort to increase our understanding of the mechanisms underlying enteric nervous system development, we screened mutagenized zebrafish for changes in the number or distribution of enteric neurons. We also established a motility assay and rescreened mutants to learn whether enteric neuron number is correlated with gastrointestinal motility in zebrafish. We describe mutations isolated in our screen that affect enteric neurons specifically, as well as mutations that affect other neural crest derivatives or have pleiotropic effects. We show a correlation between the severity of enteric neuron loss and gastrointestinal motility defects. This screen provides biological tools that serve as the basis for future mechanistic studies.     

Migration and distribution of circumpharyngeal crest cells in the chick embryo

The cardiac neural crest is located in a transitional area on the neuraxis between trunk and cephalic regions and gives rise to both the dorsolateral and ventrolateral crest cell populations. Around stage 18 of chick development, a mass of E/C8⁺ cells surrounds the postotic pharyngeal arches and forms a crescent-shaped arch, termed the circumpharyngeal ridge. Using immunohistochemistry and quail-chick chimeras, it was determined that the E/C8⁺ cell mass located in the circumpharyngeal ridge derives from the dorsolateral component of the cardiac neural crest. The ventrolateral cell population of the cardiac crest is located more medially and shows long-persistent HNK-1 immunoreactivity dorsolateral to the foregut. The crest cells that populate the gut arise from the caudal portion of the circumpharyngeal crest and are always located caudal to the caudalmost pharyngeal ectomesenchyme. Circumpharyngeal crest cells continuously populate the pharyngeal arch ectomesenchyme and enteric nervous system on the lateral side of the foregut wall, as well as the hypoglossal pathway which develops within the ventral portion of the circumpharyngeal ridge. E/C8 and HNK-1 immunoreactivity are associated with the cells migrating via the dorsolateral (circumpharyngeal) and ventrolateral pathways, respectively, with one exception: there is a population of putative crest cells along the proximal course of the vagal intestinal branch that shows both immunoreactivities around stage 20. Dil labeling of the cells in the circumpharyngeal ridge suggests that the cells are contributed from the circumpharyngeal ridge to this population. Thus, the distribution of the circumpharyngeal crest cells and their derivatives coincides with the peripheral branch distribution of the cranial nerves IX, X, and XII, whose development is selectively affected in the absence of the cardiac neural crest, the source of the circumpharyngeal crest.© Willey-Liss, Inc.     

旋股外侧动脉升支阔筋膜张肌支髂骨瓣的解剖学研究及临床意义

目的 :探讨带旋股外侧动脉升支阔筋膜张肌支髂骨瓣的解剖及应用要点。方法 :在 2 5侧经动脉灌注红色乳胶的成人下肢标本上 ,重点观测旋股外侧动脉升支阔筋膜张肌支的走行、分支、发出点和外径等。结果 :旋股外侧动脉升支的阔筋膜张肌支上行支发出点距髂前上棘平面 7.1± 2 .3cm ,外径 1.2± 0 .8mm ,该支又分出 2～ 3支外径在 0 .3mm～ 0 .5mm的小分支从阔筋膜张肌后份进入肌质 ,上行至肌起始处达髂骨 ;其下行支发出点距髂前上棘平面 7.9± 1.8cm ,外径 1.3± 0 .8mm。结论 :旋股外侧动脉升支阔筋膜张肌支髂骨瓣具有手术可行性和实际应用价值     

Lineage and development of the parasympathetic nervous system of the embryonic chick heart

 We were interested in the contribution of the cardiac neural crest to the complete anterior and posterior nerve plexus of the chick heart. This includes the pathways by which these cardiac neural crest-derived neuronal precursors enter the heart. As lineage techniques we used the traditional quail-chick chimera in combination with the newly introduced technique of retroviral reporter gene transfer to premigratory cardiac neural crest cells. Retrovirally infected embryos (n=23) and quail-chick chimeras (n=19) between stages HH27 and 40, were immunohistochemically evaluated, using the lineage markers LacZ (retroviral reporter) and QCPN (anti-quail nuclear marker), respectively and the neuronal differentiation markers HNK-1, RMO-270 and DO-170. Between stages HH27 and 33, quail-derived and LacZ positive cells were situated around the arterial cardiac vagal branches at the arterial pole, and vagal branches along the anterior cardinal veins and the sinal vagal branch at the venous pole. From stage HH35 onward, QCPN/LacZ-positive cardiac ganglia were observed throughout the anterior and posterior plexus and were mainly concentrated in the subepicardium near the distal ends of the arterial cardiac vagal branches and the sinal cardiac vagal branch respectively. From stage HH36 both the anterior and posterior plexus contained a population of large cardiac ganglion cells and a population of smaller cells along nerve branches as well as in the cardiac ganglia, which means that differentiation starts in both plexus at the same time. Furthermore only nerve fiber connections between the anterior and posterior plexus were observed. These results show that the cardiac neural crest contributes to the cardiac ganglion cells from both the entire anterior and posterior plexus. Furthermore these results suggest that these precursor cells enter the arterial pole via the arterial cardiac vagal branches and the venous pole via the sinal cardiac vagal branch without intermixing. Finally we show that in addition to the cardiac ganglia, the cardiac neural crest contributes to small myocardial glia or undifferentiated cells along nerve fibers, and some myocardial nerve fibers as well as nerve tissue in the adventitia of the large veins at the venous pole and in the adventitia of the coronary arteries. Accepted: 30 March 1998     

Temporal-spatial ablation of neural crest in the mouse results in cardiovascular defects.

Neural crest cells are thought to play a critical role in human conotruncal morphogenesis and dysmorphogenesis. Much of our understanding of the contribution of neural crest to cardiovascular patterning comes from ablation and transplantation experiments in avian species. Although fate mapping experiments in mice suggests a conservation of function, the functional requirement for neural crest in cardiovascular development in mammals has not been formally tested. We used a novel two component genetic system for the temporal-spatial ablation of neural crest in the mouse. Affected embryos displayed a spectrum of cardiovascular outflow tract defects and aortic arch patterning abnormalities. We show that the severity of the cardiovascular phenotype is directly related to the level and extent of neural crest ablation. This is the first report of cardiac neural crest ablation in mammals, and it provides important insight into the role of the mammalian neural crest during cardiovascular development.     

The formation of mesoderm and mesectoderm in 5- to 41-somite rat embryos cultured in vitro, using WGA-Au as a marker

Summary The formation of mesectodermal cells by the neural crest in 5- to 41-somite stage embryos was investigated experimentally in rat embryos cultured in vitro, using lectincoated colloidal gold as a probe. This method labelled all ectodermal cells, among them neural crest, surface ectodermal placodal and epiblastic (primitive streak) cells. The neural crest provides the mesodermal compartment of the entire head region with cells, including the primitive cranial ganglia and the branchial arches. In the head region migration of neural crest cells over a great distance (long-distance migration) was not observed. In the trunk region neural crest derived cells were mainly found to form the primitive spinal ganglia and the sympathetic trunk, once again without long-distance cell migration. Structures and tissues that supposedly were derived from the primitive streak were hardly labelled with colloidal gold. Surface ectodermal placodes were not only found at the expected sites (e.g. epibranchial placodes) but also in the ectoderm covering the transverse septum and lateral abdominal walls.