心外膜的发育

心外膜是覆盖在心脏外层的间皮组织。心外膜来源于脏壁中胚层的前心外膜,后者位于心管流入极附近。心外膜的部分细胞通过上皮间充质转化进入心外膜下层,随后形成血管内皮、成纤维和平滑肌细胞,最终导致冠脉系统的形成。心外膜细胞可能形成心肌细胞,并且可能是心脏驻留干细胞的来源。因此,它在心脏修复治疗中发挥巨大作用。本文回顾了该领域的最新研究进展并且提出了目前存在的问题。     

Flower development

Several homeotic genes controlling flower development have been characterized in Antirrhinum and Arabidopsis. Comparisons of their mutant phenotypes, expression patterns and genetic interactions have revealed that many of the basic mechanisms controlling flower development have been conserved in evolution, although important differences in the balance and interactions of genes also exist.     

Endosperm development

There is a renewal of interest in endosperm development. Recent studies are leading the way to a better understanding of fundamental processes such as cell cycle control and the mechanisms of imprinting. A more global view of interactions between the endosperm and the embryo is emerging and will initiate an integrated approach to the study of seed development.     

Middle-ear development

Laser interferometry was used to measure umbo velocity in the developing BALB/c mouse middle ear at 133 pure-tone frequencies between 2.0 kHz and 40.0 kHz, all at a constant 100 dB sound pressure level. Umbo velocities increased with age across the entire frequency range, and reached adult-like levels by about 19 days between 2.0 and 22.0 kHz. Velocities at 28.0 and 34.0 kHz took 27 and 52 days respectively to reach adult-like levels.A simple middle-ear model utilizing compliance, resistance, and inertia elements matched the general trends of our velocity results and provided an indication of the anatomical basis for the growth in umbo velocity. The model suggested that velocity development at the lowest frequencies may be attributed to increases in tympanic membrane compliance. The model also indicated that both the frictional resistance of the middle ear and the inertia of the tympanic membrane and ossicles decreased during the growth period.At frequencies below 20.0 kHz, age-related increases in umbo velocity coincided with improvements in Nj₁ thresholds recorded from the round window and evoked potential thresholds obtained from the cochlear nucleus. These results indicated that the functional development of the middle-ear plays a major role in the development of hearing in the mouse.Portions of this work were presented at the Fifteenth Meeting of the Association for Research in Otolaryngology     

Parent development

Today's parents tend to be overwhelmed with advice from many sources. In his role as family counselor, the pediatrician must understand and consider the emotional development of parents in relation to their child's development; otherwise, his advice and counsel do not "take" and he becomes tired and frustrated and angry. PARENTS PROGRESS THROUGH DEFINITE STAGES OF DEVELOPMENT: Stage 1: Learning the cues-the struggle of the parents to interpret the infant's needs. Stage 2: Learning to accept growth and development-the parent learning to accept some loss of control of the toddler. Stage 3: Learning to separate-the parent learning to allow the child to develop independently. Stage 4: Learning to accept rejection, without deserting-the struggle of the parents not to intrude and yet to be there when needed. Stage 5: Learning to build a new life having been thoroughly discredited by one's teenager-the parent learning to live independently while the teenager struggles to develop his own identity.The pediatrician who is accepting, sensitive and a good listener and who keeps in mind that parents as well as children have capacities for growth and development, will be a potent factor in promoting good parent-child relationships and many times more effective in dealing with the child in health and disease.     

Lymphatic development

The lymphatic system is essential for fluid homeostasis, immune responses, and fat absorption, and is involved in many pathological processes, including tumor metastasis and lymphedema. Despite its importance, progress in understanding the origins and early development of this system has been hampered by lack of defining molecular markers and difficulties in observing lymphatic cells in vivo and performing genetic and experimental manipulation of the lymphatic system. Recent identification of new molecular markers, new genes with important functional roles in lymphatic development, and new experimental models for studying lymphangiogenesis has begun to yield important insights into the emergence and assembly of this important tissue. This review focuses on the mechanisms regulating development of the lymphatic vasculature during embryogenesis. Birth Defects Research (Part C) 87:222–231, 2009. © 2009 Wiley‐Liss, Inc.     

Sustainable development

Perspectives on Global Change: The TARGETS Approach edited by Jan Rotmans and Bert de Vries Cambridge University Press, 1997. ￡40.00/$69.95 hbk (xv+463 pages) ISBN 0 521 62176 3.     

脂肪细胞的发育分化

脂肪组织是人体重要的能量贮存器官,同时还是一个重要的内分泌器官。适量的脂肪组织为人体所必需,但过多或过少的脂肪组织都会引起代谢综合征。脂肪细胞起源于血管基质中多潜能干细胞,这类干细胞具有自我更新和多向分化的潜能,在合适的条件下不仅可以分化为脂肪细胞,还可分化为肌肉细胞、软骨细胞和成骨细胞等中胚层来源的细胞。从多潜能干细胞到脂肪细胞的发育阶段可被分为三个阶段：（1）多潜能干细胞;（2）前脂肪细胞;（3）脂肪细胞。目前本领域的研究集中在干细胞定向为前脂肪细胞的机理以及这些定向为前脂肪细胞的干细胞的来源。该文将对从多潜能干细胞发育分化为成熟脂肪细胞的过程进行详细的阐述。