SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3046101388> ?p ?o ?g. }

Showing items 1 to 100 of ±134 with 100 items per page.

W3046101388 abstract "ABSTRACT One of the decisive questions about human gross anatomy is unmatching the adult branching pattern of the spinal nerve to the embryonic lineages of the peripheral target muscles. The two principal branches in the adult anatomy, the dorsal and ventral rami of the spinal nerve, innervate the intrinsic back muscles (epaxial muscles), as well as the body wall and appendicular muscles (hypaxial muscles), respectively. However, progenitors from the dorsomedial myotome develop into the back and proximal body wall muscles (primaxial muscles) within the sclerotome-derived connective tissue environment. In contrast, those from the ventrolateral myotome develop into the distal body wall and appendicular muscles (abaxial muscles) within the lateral plate-derived connective tissue environment. Thus, the ventral rami innervate muscles that belong to two different embryonic compartments. Because strict correspondence between an embryonic compartment and its cognate innervation is a way to secure the development of functional neuronal circuits, this mismatch indicates that we may need to reconcile our current understanding of the branching pattern of the spinal nerve with regard to embryonic compartments. Accordingly, we first built a model for the branching pattern of the spinal nerve, based on the primaxial-abaxial distinction, and then validated it using mouse embryos. In our model, we hypothesized the following: 1) a single spinal nerve consists of three nerve components: primaxial compartment-responsible branches, a homologous branch to the canonical intercostal nerve bound for innervation to the abaxial compartment in the ventral body wall, and a novel class of nerves that travel along the lateral cutaneous branch to the appendicles; 2) the three nerve components are discrete only during early embryonic periods but are later modified into the elaborate adult morphology; and 3) each of the three components has its own unique morphology regarding trajectory and innervation targets. Notably, the primaxial compartment-responsible branches from the ventral rami have the same features as the dorsal rami. Under the above assumptions, our model comprehensively describes the logic for innervation patterns when facing the intricate anatomy of the spinal nerve in the human body. In transparent whole-mount specimens of embryonic mouse thoraces, the single thoracic spinal nerve in early developmental periods trifurcated into superficial, deep, and lateral cutaneous branches; however, it later resembled the adult branching pattern by contracting the superficial branch. The superficial branches remained segmental while the other two branches were free from axial restriction. Injection of a tracer into the superficial branches of the intercostal nerve labeled Lhx3-positive motoneurons in the medial portion of the medial motor column (MMCm). However, the injection into the deep branches resulted in retrograde labeling of motoneurons that expressed Oct6 in the lateral portion of the medial motor column (MMCl). Collectively, these observations on the embryonic intercostal nerve support our model that the spinal nerve consists of three distinctive components. We believe that our model provides a framework to conceptualize the innervation pattern of the spinal nerve based on the distinction of embryonic mesoderm compartments. Because such information about the spinal nerves is essential, we further anticipate that our model will provide new insights into a broad range of research fields, from basic to clinical sciences." @default.
W3046101388 created "2020-08-03" @default.
W3046101388 creator A5006470202 @default.
W3046101388 creator A5017453886 @default.
W3046101388 creator A5028014599 @default.
W3046101388 creator A5049954451 @default.
W3046101388 creator A5063423983 @default.
W3046101388 creator A5088028612 @default.
W3046101388 date "2020-07-30" @default.
W3046101388 modified "2023-10-16" @default.
W3046101388 title "Three-Component Model of the Spinal Nerve Branching Pattern, based on the View of the Lateral Somitic Frontier and Experimental Validation" @default.
W3046101388 cites W165536231 @default.
W3046101388 cites W1799669212 @default.
W3046101388 cites W1914845954 @default.
W3046101388 cites W1951905282 @default.
W3046101388 cites W1964151115 @default.
W3046101388 cites W1966096547 @default.
W3046101388 cites W1970729119 @default.
W3046101388 cites W1971254008 @default.
W3046101388 cites W1981625517 @default.
W3046101388 cites W1982234682 @default.
W3046101388 cites W1982630660 @default.
W3046101388 cites W1983376914 @default.
W3046101388 cites W1988099244 @default.
W3046101388 cites W1988824884 @default.
W3046101388 cites W1990049285 @default.
W3046101388 cites W1996616952 @default.
W3046101388 cites W1997653267 @default.
W3046101388 cites W2004008235 @default.
W3046101388 cites W2004409409 @default.
W3046101388 cites W2007718199 @default.
W3046101388 cites W2008030699 @default.
W3046101388 cites W2009824931 @default.
W3046101388 cites W2012313525 @default.
W3046101388 cites W2012802764 @default.
W3046101388 cites W2026770409 @default.
W3046101388 cites W2030493369 @default.
W3046101388 cites W2031619448 @default.
W3046101388 cites W2039501422 @default.
W3046101388 cites W2043905106 @default.
W3046101388 cites W2048284315 @default.
W3046101388 cites W2050006573 @default.
W3046101388 cites W2056835595 @default.
W3046101388 cites W2068391384 @default.
W3046101388 cites W2072808488 @default.
W3046101388 cites W2075001701 @default.
W3046101388 cites W2079686908 @default.
W3046101388 cites W2081235375 @default.
W3046101388 cites W2089045623 @default.
W3046101388 cites W2089304691 @default.
W3046101388 cites W2093820762 @default.
W3046101388 cites W2101545913 @default.
W3046101388 cites W2104664767 @default.
W3046101388 cites W2105669185 @default.
W3046101388 cites W2123472374 @default.
W3046101388 cites W2127335826 @default.
W3046101388 cites W2128732581 @default.
W3046101388 cites W2148146399 @default.
W3046101388 cites W2156792520 @default.
W3046101388 cites W2176077507 @default.
W3046101388 cites W2320475195 @default.
W3046101388 cites W2524064044 @default.
W3046101388 cites W2546990456 @default.
W3046101388 cites W2593856278 @default.
W3046101388 cites W2671423752 @default.
W3046101388 cites W2747461422 @default.
W3046101388 cites W2906150387 @default.
W3046101388 cites W2948937638 @default.
W3046101388 cites W4238929436 @default.
W3046101388 cites W49533206 @default.
W3046101388 doi "https://doi.org/10.1101/2020.07.29.227710" @default.
W3046101388 hasPublicationYear "2020" @default.
W3046101388 type Work @default.
W3046101388 sameAs 3046101388 @default.
W3046101388 citedByCount "0" @default.
W3046101388 crossrefType "posted-content" @default.
W3046101388 hasAuthorship W3046101388A5006470202 @default.
W3046101388 hasAuthorship W3046101388A5017453886 @default.
W3046101388 hasAuthorship W3046101388A5028014599 @default.
W3046101388 hasAuthorship W3046101388A5049954451 @default.
W3046101388 hasAuthorship W3046101388A5063423983 @default.
W3046101388 hasAuthorship W3046101388A5088028612 @default.
W3046101388 hasBestOaLocation W30461013881 @default.
W3046101388 hasConcept C105702510 @default.
W3046101388 hasConcept C111368507 @default.
W3046101388 hasConcept C127313418 @default.
W3046101388 hasConcept C140530291 @default.
W3046101388 hasConcept C169760540 @default.
W3046101388 hasConcept C196843134 @default.
W3046101388 hasConcept C203635412 @default.
W3046101388 hasConcept C2775958995 @default.
W3046101388 hasConcept C2779018604 @default.
W3046101388 hasConcept C2779297532 @default.
W3046101388 hasConcept C2780775167 @default.
W3046101388 hasConcept C2780999072 @default.
W3046101388 hasConcept C518705261 @default.
W3046101388 hasConcept C54355233 @default.
W3046101388 hasConcept C86803240 @default.
W3046101388 hasConcept C87073359 @default.
W3046101388 hasConcept C95444343 @default.