Lee Ji Yeoun, Kim Saet Pyoul, Kim Shin Won, Park Sung-Hye, Choi Jung Won, Phi Ji Hoon, Kim Seung-Ki, Pang Dachling, Wang Kyu-Chang
Division of Pediatric Neurosurgery, Seoul National University Children's Hospital, Seoul National University College of Medicine, 101 Daehak-ro, Jongno-gu, Seoul 110-769, Republic of Korea.
Childs Nerv Syst. 2013 Sep;29(9):1683-8. doi: 10.1007/s00381-013-2196-3. Epub 2013 Jun 19.
Terminal myelocystocele (TMC) is thought to be caused by a misstep during secondary neurulation. However, due to the paucity of data on secondary neurulation and the rarity of TMC, proofs of this pathogenetic mechanism are unavailable. Based on a previous observation that TMC resembles a step of secondary neurulation in chick, a closer look was taken at secondary neurulation of chick embryos focusing on the cerebrospinal fluid-filled distal neural tube (terminal balloon).
Chick embryos at Hamburger and Hamilton (H-H) stages of 28, 30, 33, 35, 37, and 40 were harvested. Hematoxying-eosin staining, additional immunohistochemistry (laminin, cytokeratin, nestin), and scanning electron microscopy were performed.
In H-H stages 28 to 30, after merging of the lumina of the primary and secondary neural tubes, the caudal end of the confluent tube dilates into a balloon-like structure (terminal balloon). As the proximal tube progressively becomes narrower, the terminal balloon dilates even further, and its wall fuses with the surface ectoderm (H-H stage 33). Later in H-H stages 35 to 40, the terminal balloon shrinks and becomes detached from the surface ectoderm and ultimately disappears, as the proximal lumen of the secondary neural tube continues to collapse.
A dilated balloon doubtlessly exists in the terminal secondary neural tube in chick embryos, and its subsequent disappearance occurs in a variable time course and sequence. Arrest of apoptosis resulting in failure of detachment of the terminal balloon from the surface ectoderm may well be the basis for human TMC.
终末脊髓脊膜膨出(TMC)被认为是继发神经胚形成过程中出现差错所致。然而,由于继发神经胚形成的数据匮乏以及TMC的罕见性,这种发病机制的证据尚不明确。基于之前观察到TMC类似于鸡胚继发神经胚形成的一个步骤,我们对鸡胚的继发神经胚形成进行了更深入的研究,重点关注充满脑脊液的远端神经管(终末球囊)。
收集处于汉堡和汉密尔顿(H-H)28、30、33、35、37和40阶段的鸡胚。进行苏木精-伊红染色、额外免疫组化(层粘连蛋白、细胞角蛋白、巢蛋白)以及扫描电子显微镜检查。
在H-H 28至30阶段,初级和次级神经管腔融合后,融合管的尾端扩张成气球样结构(终末球囊)。随着近端管逐渐变窄,终末球囊进一步扩张,其壁与表面外胚层融合(H-H 33阶段)。在H-H 35至40阶段后期,随着次级神经管近端管腔持续塌陷,终末球囊收缩并与表面外胚层分离,最终消失。
鸡胚终末次级神经管中无疑存在扩张的球囊,其随后消失的时间进程和顺序各不相同。凋亡受阻导致终末球囊无法与表面外胚层分离很可能是人类TMC的基础。
