AI Article Synopsis
- The processes of primary and secondary neurulation, which lead to spinal cord formation, are not fully understood in humans due to difficulties accessing embryos at the relevant stages (3-7 weeks post-conception).
- Analysis of 108 human embryos reveals that while primary neurulation is similar to that in mice, it has distinct differences; secondary neurulation begins later and forms a single lumen, unlike the multiple lumens seen in chicks.
- Key differences in neurulation timing between humans and mice were noted, such as the rate of somite formation and the termination of axial elongation associated with apoptosis in the embryonic tailbud; these findings can aid current research on neurulation using stem cell-derived organoids
Article Abstract
Primary and secondary neurulation - processes that form the spinal cord - are incompletely understood in humans, largely due to the challenge of accessing neurulation-stage embryos (3-7 weeks post-conception). Here, we describe findings from 108 human embryos, spanning Carnegie stages (CS) 10-18. Primary neurulation is completed at the posterior neuropore with neural plate bending that is similar, but not identical, to the mouse. Secondary neurulation proceeds from CS13 with formation of a single lumen as in mouse, not coalescence of multiple lumens as in chick. There is no evidence of a 'transition zone' from primary to secondary neurulation. Secondary neural tube 'splitting' occurs in 60% of proximal human tail regions. A somite is formed every 7 hr in human, compared with 2 hr in mice and a 5 hr 'segmentation clock' in human organoids. Termination of axial elongation occurs after down-regulation of and in the CS15 embryonic tailbud, with a 'burst' of apoptosis that may remove neuro-mesodermal progenitors. Hence, the main differences between human and mouse/rat spinal neurulation relate to timing. Investigators are now attempting to recapitulate neurulation events in stem cell-derived organoids, and our results provide 'normative data' for interpretation of such research findings.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11620743 | PMC |
| http://dx.doi.org/10.7554/eLife.88584 | DOI Listing |
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