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本文引用的文献

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Mastication in springhares, Pedetes capensis: A cineradiographic study.南非跳兔(Pedetes capensis)的咀嚼:一项X线电影摄影研究。
J Morphol. 1990 Sep;205(3):353-367. doi: 10.1002/jmor.1052050310.
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ONTOGENY AND PHYLOGENY IN HORSE SKULL EVOLUTION.马颅骨进化中的个体发育与系统发育
Evolution. 1984 Jan;38(1):1-15. doi: 10.1111/j.1558-5646.1984.tb00254.x.
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Jaw muscle functional anatomy in northern grasshopper mouse, Onychomys leucogaster, a carnivorous murid.北方蝗虫鼠(白腹林鼠,一种食肉性鼠科动物)颌肌的功能解剖学
J Morphol. 2006 Aug;267(8):987-99. doi: 10.1002/jmor.10443.
4
The evolution of fossoriality and the adaptive role of horns in the Mylagaulidae (Mammalia: Rodentia).袋鼠科(哺乳纲:啮齿目)掘地习性的演化及角的适应性作用
Proc Biol Sci. 2005 Aug 22;272(1573):1705-13. doi: 10.1098/rspb.2005.3171.
5
Internal architecture, origin-insertion site, and mass of jaw muscles in Old World hamsters.旧大陆仓鼠颌肌的内部结构、起止点及质量
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6
Higher-level systematics of rodents and divergence time estimates based on two congruent nuclear genes.基于两个一致的核基因的啮齿动物高级系统学及分歧时间估计
Mol Phylogenet Evol. 2003 Mar;26(3):409-20. doi: 10.1016/s1055-7903(02)00304-4.
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Rodent phylogeny and a timescale for the evolution of Glires: evidence from an extensive taxon sampling using three nuclear genes.啮齿动物系统发育与兽亚纲演化的时间尺度:来自使用三个核基因的广泛分类群抽样的证据。
Mol Biol Evol. 2002 Jul;19(7):1053-65. doi: 10.1093/oxfordjournals.molbev.a004164.
8
Phylogeny of rodentia (Mammalia) inferred from the nuclear-encoded gene IRBP.从核编码基因IRBP推断啮齿目(哺乳纲)的系统发育。
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9
Molecular phylogeny and divergence time estimates for major rodent groups: evidence from multiple genes.主要啮齿动物类群的分子系统发育与分歧时间估计:来自多个基因的证据
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10
Variance of molecular datings, evolution of rodents and the phylogenetic affinities between Ctenodactylidae and Hystricognathi.分子定年的方差、啮齿动物的进化以及栉趾鼠科与豪猪亚目之间的系统发育亲缘关系
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红腹田鼠和松鼠型啮齿动物切齿咬噬功能的解剖学研究-第 1 部分:咀嚼肌、颅骨形状和挖掘行为。

Functional anatomy of incisal biting in Aplodontia rufa and sciuromorph rodents - part 1: masticatory muscles, skull shape and digging.

机构信息

Departments of Occupational and Physical Therapy, Governors State University, University Park, Ill. 60484, USA. r-druzinsky @ govst.edu

出版信息

Cells Tissues Organs. 2010;191(6):510-22. doi: 10.1159/000284931. Epub 2010 Feb 16.

DOI:10.1159/000284931
PMID:20160428
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2883844/
Abstract

Traditionally, rodents have been grouped into suborders distinguished largely on the basis of characteristics of the jaw adductor muscles and other features of the masticatory apparatus. The three classic suborders are: Sciuromorpha (squirrels), Myomorpha (rats and mice), and Hystricomorpha (porcupines and the South American caviomorph rodents). Protrogomorph rodents are thought to represent the primitive condition of rodent masticatory muscles. Aplodontia rufa, the mountain beaver, is the only living protrogomorphous rodent. The present work is a detailed comparison of the masticatory apparatus in A. rufa and Marmota monax, the woodchuck. But the mandibular region of A. rufa appears remarkable, unlike anything found in other rodents. Is A. rufa a reasonable representative of the primitive, protrogomorphous condition? A.rufa is a member of the aplodontoid-sciuroid clade with a wide and flat skull. The large temporalis and mandibular apophyses of A. rufa are features related to its relatively wide skull. Such features are found in less dramatic forms in other sciuromorphous species and the basic arrangement of the masticatory muscles of A. rufa is similar to the arrangement seen in sciuromorphs.

摘要

传统上,啮齿动物被分为亚目,主要根据颌内收肌和咀嚼器官的其他特征来区分。三个经典的亚目是:松鼠形亚目(松鼠)、鼠形亚目(大鼠和小鼠)和豪猪形亚目(豪猪和南美的囊鼠类啮齿动物)。原古形啮齿动物被认为代表了啮齿动物咀嚼肌肉的原始状态。山毛榉鼠,山獭,是唯一现存的原古形啮齿动物。本工作对 A. rufa 和 Marmota monax,即土拨鼠的咀嚼器官进行了详细比较。但是 A. rufa 的下颌区域看起来很特别,与其他啮齿动物的任何特征都不同。A. rufa 是否是原始、原古形状态的合理代表?A. rufa 是aplodontoid-sciuroid 分支的一员,头骨宽而平。A. rufa 的颞肌和下颌骨突起很大,这是与其相对较宽的头骨有关的特征。这些特征在其他松鼠形物种中以不太显著的形式出现,而 A. rufa 的咀嚼肌的基本排列与松鼠形动物相似。