大口黑鲈和尖吻鲈骨骼系统的比较研究

对大口黑鲈和尖吻鲈的骨骼系统进行了比较研究。结果表明 :从整体看 ,大口黑鲈的脑颅较宽 ,吻短钝 ,眼后头部短 ;尖吻鲈的脑颅狭窄 ,吻部尖长而突出 ,眼后头部较长。各部分的骨骼特征 :大口黑鲈脑颅的中筛骨、侧筛骨、额骨、上枕骨、上耳骨、翼耳骨和围眶骨等与尖吻鲈有明显的区别 ;大口黑鲈咽颅中的前颌骨、齿骨、中翼骨、鳃盖骨骼、角舌骨、尾舌骨、下咽骨等与尖吻鲈又有显著的差异 ;大口黑鲈附属骨骼中的肩带骨、腰带骨、脊椎骨等有很大的不同。这些差异和不同可作为科间或属间分类依据。     

异鲴的骨骼形态及其属的分类位置

对异鲴的骨骼形态进行了详细的描述并与丹亚科及鲴亚科代表种的骨骼特征进行了比较。结果显示异鲴与丹亚科在骨骼学性状缺乏共同离征,一系列的离征却表明它与再生鲴亚科鱼类紧密相关。这些离征包括：咽骨形态独特,前臂略长或与后臂等长;下咽齿侧扁,有明显的咀嚼面;基枕骨具有向下弯曲的基枕骨突,咽突而发达,椭圆形且向前突出;穿行于基枕骨的背大动脉通道接近咽突长;副蝶骨具有发达的龙骨突;前上颌骨短宽,下边缘为软骨;上颌骨外侧具突起;齿骨前背缘有外侧等。异鲴之置于丹亚科仅依据他们在围眶骨系的形态及排列上的相似性,而它和鲴亚科鱼类具有的一些共同离征表明它们可以形成姐妹群。因此,异鲴属在鲤科中的分类位置应该更加接近鲴亚科。     

中国鲽形目鱼类骨骼的研究：Ⅲ,脑颅骨

本文研究了中国鲽形目8科、27属和约40种的脑颅骨;指出其脑颅骨的最显著特征是前部左右不对称,并首次发现鳒科无基蝶骨(与Berg,1940,1955及Nelson,1984的记载不同),副蝶骨延及基枕骨腹侧后端或附近(与Amaoka,1969及Ochiai,1963的记载也不同)和冠鲽科无眶间突且左右前额骨互连。还依它们脑颅骨的异同,探讨了其演化程度,并拟有中国鲽形目各亚目及科的检索表。     

董氏中华盗龙(兽脚类:异特龙超科)脑颅新知:筛区、颅腔解剖和具气腔(英文)

董氏中华盗龙(Sinraptor dongi) 是产自中国西北部新疆侏罗纪石树沟组上部的一种大型兽脚类。其正型标本包括了保存完好的脑颅,这是在最近的化石修理中额外发现的。脑颅中骨化筛骨的横切面为 U 形。在脑颅的解剖方位,蝶筛骨和眶蝶骨之间有一未骨化空间,表明该恐龙存活时具有软骨质的中隔蝶骨。利用乳胶颅腔模型和 CT 扫描技术对颅腔和含气隐窝的形态进行了研究,发现了一些此前未描述过的特点。其中尤为引人注目的是,发育良好的尾鼓室隐窝[一般认为是虚骨龙类(coelurosaurs) 的典型特征]以及基蝶骨隐窝和相关气腔的内部形态。侧鼓室隐窝和基蝶骨隐窝有纵向通道连接,很可能同时具有气腔和血管功能。模型也表明,颅腔没有髓质隆起,小脑绒球隐窝的开孔为沙漏状。若不包含嗅束和嗅球,颅腔容积为 95 ml,脑容商在其他基干坚尾龙类( tetanurans) 的范围内。虽然这些类群的第Ⅱ-Ⅳ对脑神经相对位置各有差异,但前脑、中脑和后脑之间的角度与鲨齿龙类( carcharodontosaurids) [鲨齿龙(Carcharodontosaurus) 及南方巨兽龙(Giganotosaurus) ]相似。第Ⅸ,Ⅹ和Ⅺ对脑神经穿过一个半月形的孔。在异特龙超科( Allosauroidea) 中,中华盗龙(Sinraptor) 在颅腔形态上与鲨齿龙、南方巨兽龙和异特龙( Allosaurus) 的相似程度比它与高棘龙(Acrocanthosaurus) 的相似程度更高。     

鳞骨在哺乳动物进化过程中的形态变化

本文对现代兽类哺乳动物的鳞骨位于围耳骨前方,并参加脑颅侧壁构成的原因和方式作了试探性的解释─—由于脑颅各功能组合部分的生长发育是异时的和异速的。颧弓的较早形成把鳞骨和颌部固结在一起,而鳞骨的围耳骨突萎缩,脱离开围耳骨,又为鳞骨前移提供了方便。鳞骨的顶骨突在因脑的膨大所产生的顶骨和耳部之间的“裂隙”处加入到脑腔侧壁,与前方的异蝶骨和后方的岩耳骨愈合在一起,形成了高级兽类哺乳动物类型的脑颅侧壁。     

鳞骨在哺乳动物进行过程中的形态变化

本对现代兽类哺乳动物的鳞骨位于围耳骨前方,并参加脑颅侧壁构成的原因和方式作了试探性的解释,由于脑脑颅各功能组合部分的生长发育是异时的和异速的。颧弓的较早形成把鳞骨和颌部固结在一起,而磷骨的围耳骨突萎缩,脱离开围耳骨,又为鳞骨前移提供了方便。鳞骨的顶骨突在因脑的膨大所产生的顶骨和耳部之间的“裂隙”处加入到及腔侧壁,与前方的异蝶骨和后方的岩耳骨愈合在一起,形成了高级兽类哺乳动物类型的脑颅侧壁。     

内蒙古中部新发现的始施氏貘(哺乳纲,奇蹄目)头骨材料(英文)

记述了产自内蒙古呼和勃尔和剖面阿山头组的始施氏貘(Schlosseria magister)幼年头骨、头骨碎片及产自额尔登敖包底白层的S.magister成年头骨。幼年头骨在脊齿貘科属首次描述,成年头骨材料也是目前S.magister中首次描述。幼年头骨主要特征如下:头骨细长,脑颅部略有扩张,有眶后突,眶后收缩明显,矢状脊轻微发育;鼻切迹浅,位于前臼齿列之前,由前颌骨和鼻骨构成;眼眶大,眶前缘位于M1后部上方,眶下孔位于DP3-4之上;基蝶骨向后向中央逐渐加厚,末端隆起;翼蝶骨很大,从腹面看向后向背侧扩展,末端形成三角形的翼蝶骨突,覆盖在卵圆孔上;岩骨岬部表面有内颈动脉及其分支留下的3条沟痕;最内侧的为内颈动脉内侧沟,沿着岬部弯曲前行至最前部;镫骨动脉沟短小,横跨在圆窗前腹侧;岬动脉沟最长,起始于卵圆窗前内侧,沿岬部向前延伸;弓形下窝所在位置平滑,无凹陷。S.magister乳颊齿主要特征如下:DP2冠面大致呈三角形,前窄后宽,前缘较尖,长明显大于宽;外脊上仅有一个中央主尖前尖,一个非常不明显的小棱(可能为雏形的原脊)紧贴在前尖后舌侧壁上;前、后附尖不明显。DP3冠面呈梯形,与DP2相比明显增大,亚臼齿化,前附尖和后附尖略大,原、后脊明显。前尖大,后尖尚未分离;原尖很弱,几乎无法辨认,原脊低且不发育;次尖大而钝,比原尖更靠舌侧,后脊比原脊略发育,中部具小的后小尖;后脊在次尖处拐向后唇侧,使得磨蚀面呈V形。DP4冠面近方形,完全臼齿化,后尖已从外脊上分化出来,比前尖稍小,向舌侧倾斜,后尖肋明显;舌侧尖、脊发育完好,原尖和次尖大而钝,原脊、后脊近乎平行,比DP3的更高更长;两条脊分别在原尖和后尖处拐向后唇侧方,形成V形的磨蚀面。S.magister在由幼年向成年转变的过程中,主要变化趋势如下:1)吻部特征不同,主要表现为鼻切迹的位置、形态以及与之相关的前颌骨、上颌骨形态的差异。幼年头骨的鼻切迹位于前臼齿列之前,由前颌骨和鼻骨组成;成年头骨的鼻切迹后缩至M1-2之上,由鼻骨和上颌骨组成,并且因鼻切迹后缩造成鼻骨不与前颌骨接触。幼年和成年个体上颌骨的整体形态,眶前窝、眶下孔的位置和形态都差异显著。2)与咀嚼功能相关的结构改变。幼年个体的矢状脊微弱,而成年个体的则高且突起,暗示了后者具有相对强大的颞肌,以适应咀嚼功能。对比发现,S.magister与Lophialetes expeditus成年头骨在大小、整体形态和一些具有分类意义的特征上(如鼻骨和泪骨、前颌骨的接触方式,眶后突、关节后突、下颌关节窝的形状,矢状脊的高度等)非常接近。参照童永生、雷奕振(1984)对脊齿貘类头骨的划分方法,将Schlosseria magister的头骨与L.expeditus的划为一组,同时纠正了原有划分方案中存在的问题。     

中国陆相上三叠统第一个初龙形类动物(英文)

初步研究了山西省永和县桑壁镇铜川组二段产出的两件初龙形类化石标本 (IVPPV1 2 3 78,V 1 2 3 79) ,在此基础上建立了一新属新种———桑壁永和鳄 (Yonghesuchussangbiensisgen .etsp .nov .)。它以下列共存的衍生特征区别于其他初龙形类 (archosauriforms) :1 )吻部前端尖削 ;2 )眶前窝前部具一凹陷 ;3 )眶前窝与外鼻孔间宽 ;4)眶后骨下降突的后 2 / 3宽且深凹 ;5 )基蝶骨腹面有两个凹陷 ;6 )齿骨后背突相当长 ;7)关节骨的反关节区有明显的背脊 ,有穿孔的翼状的内侧突 ,以及指向前内侧向和背向的十分显著的后内侧突。由于缺乏跗骨的形态信息 ,目前很难通过支序分析建立永和鳄的系统发育关系。但可以通过头骨形态来推测永和鳄在初龙形类中的系统位置。永和鳄有翼骨齿 ,这表明它不属于狭义的初龙类 (archosaurians)。其通过内颈动脉脑支的孔位于基蝶骨的前侧面而不是腹面 ,在这点上永和鳄比原鳄龙科 (Proterochampsidae)更进步 ,这表明与后者相比永和鳄和狭义的初龙类的关系可能更近。在中国早期的初龙形类中 ,达坂吐鲁番鳄 (Turfanosuchusdabanensis)与桑壁永和鳄最接近 ,但前者由于内颈动脉脑支的孔腹位而比后者更为原始。根据以上头骨特征以及枢后椎椎体之间间椎体的存在与否 ,推测派克鳄 (Euparkeri     

南京1号直立人头骨与肯尼亚KNM-ER 3733人类头骨化石的形态比较

KNM-ER 3733人类头骨化石的年代为距今1.78百万年,1975年发现于肯尼亚。Walker和Leakey注意到这具头骨与周口店直立人的在脑颅形态上很相近,但二者在年代上相差大约1百万年,故认为直立人形态在这1百万年期间是稳定的。长期来此观点缺乏更多的人类化石证据来支持。1993年在中国发现了南京1号人类头骨化石。该头骨与KNM-ER 3733头骨一样兼具脑颅和面颅,且都属于成年女性个体,但南京1号人类头骨化石的年代比KNM-ER 3733人类头骨化石的要晚大约1百万年。因此,南京1号人类头骨是目前所知的可用来验证直立人头骨形态是否在1百万年期间保持稳定的唯一合适的人类头骨化石材料。形态比较表明,这两个人类头骨化石的脑颅虽然在眶上圆枕上沟的发育程度、眶后收缩的程度、额骨横向隆起的程度、角圆枕和乳后突的发育与否、顶骨形状以及骨壁厚度的表现上有所差异,但有更多的形态性状显示出相近。这些相近表现在脑颅的长、宽、高值上;颅容量上;脑颅的低矮性上;脑颅最大宽之位置上;额骨、顶骨、枕骨之矢弧值的比例上;眶上圆枕的纤细上;顶骨的大小和矢向扁平性上;颞线位置和颞鳞顶缘的形状上;枕鳞的低宽形状上;上枕鳞与下枕鳞之间的转折形状和比例上;枕骨圆枕和枕骨圆枕上沟的发育程度上等。这两具头骨的面颅虽然有同属突颌型的面角、皆发育有鼻骨间嵴、两鼻骨组成的上部宽度与下部宽度皆差别很大,但有更多的形态性状显示出差别。这些差别表现在面型上、颜面上部扁平度上、眶形和眶型上、上颌额突外侧面的朝向上、鼻骨横向隆起程度上、鼻梁外突程度上、鼻型上、颧骨下缘外展程度上、颊高上、颧上颌下缘的形状上、上颌颧突基部的位置上以及颧结节的位置上等。因此,南京1号头骨与KNM-ER 3733头骨之间在脑颅上显示出较多的相近性状,在面颅上则显示出较多的相异性状。脑颅方面的相近性状大多具有分类上的鉴别价值。这两个头骨脑颅形态的相近支持把KNM-ER 3733头骨鉴定为"直立人"的观点;也提示了南京1号头骨的脑颅似乎保持着1百多万年前的"祖先"形态。如果直立人的某些成员在至少1百万年期间保持着形态稳定的话,则这种形态上的稳定主要是表现在脑颅形态上。这两具头骨的面颅形态上较大差异的意义,目前尚不清楚。     

金龙鱼(Scleropages:Osteoglossomorpha)化石的首次发现（英文）

金龙鱼化石的鳞片和骨骼碎片在过去时有报道,但鉴定并非十分可靠,因为在骨舌鱼科鱼类中这些鳞片和骨骼十分相似。首次记述了保存完美的金龙鱼化石,标本产于湖南湘乡下湾铺组和湖北松滋洋溪组,确立为骨舌鱼科金龙鱼属一新种:中华金龙鱼Scleropages sinensis sp.nov.。新种与现生金龙鱼(Scleropages)在头部骨骼、尾骨骼、各鳍的形状和位置以及具有网状鳞片等方面极为相似,因而归入该属。然而,新种在以下特征上不同于金龙鱼的现生种:鼻骨无纹饰,鼻骨上的感觉管显露于沟内,感觉管联合不经过顶骨,翼耳骨侧向加厚,眶前骨上的感觉孔大,眼眶后的眶下骨不完全覆盖前鳃盖骨上支,其宽高比例为0.75而非现生种的1–1.2,前鳃盖骨后下角变尖,鳃盖骨后下缘凹形、下端变尖,匙骨背突长大,脊椎46–48,椎体横突短小,胸鳍十分长大,上下两端的尾鳍条和内部鳍条等长。亚洲的现生种发现于各种河流和小溪中,比较喜欢水草茂盛的静水环境,一般游弋于表层水中,以鱼虾、昆虫等为食,新种中华金龙鱼也应该有相似的生长环境和食性。新种似具有性二形性,雄鱼体形略纤细,头部略大,口裂更深。中华金龙鱼化石的发现,说明金龙鱼属(Scleropages)和骨舌鱼属(Osteoglossum)在早始新世以前就已经分化,这对解释骨舌鱼类的跨洋分布具有十分重要的意义。     

Cranial osteogenesis in Monodelphis domestica (Didelphidae) and Macropus eugenii (Macropodidae)

The pattern of onset and general rate of cranial ossification are compared in two marsupials, Monodelphis domestica (Didelphidae) and Macropus eugenii (Macropodidae). In both species a similar suite of bones is present at birth, specifically those surrounding the oral cavity and the exoccipital, and in both postnatal events follow a similar course. The facial skeleton matures more rapidly than the neurocranium, which is characterized by an extended period of ossification. Most dermal bones begin ossification before most endochondral bones. Endochondral bones of the neurocranium are particularly extended in both the period of onset of ossification and the rate of ossification. These data confirm suggestions that morphology at birth is conservative in marsupials and we hypothesize that the pattern of cranial osteogenesis is related to two distinct demands. Bones that are accelerated in marsupials are correlated with a number of functional adaptations including head movements during migration, attachment to the teat, and suckling. However, the very slow osteogenesis of the neurocranium is probably correlated with the very extended period of neurogenesis. Marsupials appear to be derived relative to both monotreme and placental mammals in the precocious ossification of the bones surrounding the oral cavity, but share with monotremes an extended period of neurocranial osteogenesis. © 1993 Wiley-Liss, Inc.     

Osteocranial development in the viviparous surfperch Amphistichus argenteus (pisces: Embiotocidae)

The development of the cranial and branchial skeleton of the surfperch Amphistichus argenteus, a member of the family Embiotocidae, is described, and phylogenetic and functional aspects of the skull development of this species are discussed. The earliest bones to appear are those dermal elements of the branchial skeleton involved with feeding, and the bones, both dermal and endochondral, located in the basicranial region of the neurocranium. These are followed by dermal bones associated with the lateral line system and finally by the remainder of the bones of the branchial skeleton and the cartilaginous bones of the otic capsules. The last bone to develop is the ethmoid.     

Late Permian Discordichthyiformes (Osteichthyes) from European Russia

New Late Permian fishes combining features characteristic of several classes are analyzed and redescribed. They were assigned to the family Discordichthyidae of the order Discordichthyiformes comprising three genera and four species: Mutovinia stella Minich, Geryonichthys longus A. Minich, G. burchardi A. Minich, and Discordichthys spinifer A. Minich (Minikh, 1998). A new species, Mutovinia sennikovi sp. nov., is described. Due to rapid evolutionary replacement, discordichthyids are rather useful stratigraphically. The photographs of the skeleton and membrane bones of these fishes are published for the first time.     

中国鲀形目鱼类嗅觉器官类型的研究

嗅觉器官是鱼类的一种重要感觉器官,它感受由化学而引起的刺激。各种鱼类的感觉器官是十分不同的,不少学者研究了它的构造及其生理机能。以往对鲀形目鱼的嗅觉器官构造的研究报道甚少,大多注意了它的外鼻孔的形态变化,仅在少数文章(Hora,1975)提到鲀形目鱼的嗅觉器官极不发达。为了弄清它的构造特点,解剖观察了中国鲀形目代表性种类的嗅觉器官,对它们的构造特征进行了比较研究,发现它们在各不同分类阶元有独特的构造。     

Craniofacial growth of fetal Macaca nemestrina: A cephalometric roentgenographic study

The prenatal growth of the macaque craniofacial skeleton is described using lateral radiographs of 82 fetal and 25 neonatal Macaca nemestrina whose known gestational ages range from 50 to 186 days. The ossification sequence of the craniofacial bones resembles that in the human fetus. During gestation, the macaque neurocranium loses its round, globular shape, becoming flattened and elongated in an anteroposterior direction. In contrast, the morphologic pattern of the face is established early in fetal life, and little change takes place during the remaining prenatal period. The macaque craniofacial dimensions develop along the general skeletal growth pattern, unlike the human craniofacial dimensions, which follow an intermediate pattern between the neural and general skeletal patterns. However, despite minor differences, the macaque and human fetal faces follow the same basic patterns of growth.     

Early development of the cephalic skeleton of Barbus barbus (Teleostei, Cyprinidae)

The inception, and development of the cephalic skeleton of Barbus barbus from hatching to 24 days passes through periods of fast and slow growth; these rates are not the same in different parts of the skull. Trabeculae, parachordal plates, Meckelian cartilages and hyposymplectics are present at hatching. Then the cartilaginous floor of the neurocranium develops, the pars quadrata, the hyoid bars and branchial arches elements appear shortly before the first movable dermal bones, the dentaries, maxillae and opercles. The first bone of the braincase to appear is the parasphenoid; other bones develop subsequently and at the same time: the angular, quadrate, interopercle and fifth ceratobranchial. Later the splanchnocranium continues to develop at a relatively fast rate while the neurocranium shows little growth. The braincase does not begin to close before the 24th day, nor do the first bones of the skull roof appear, while the bucco-pharyngeal apparatus is complete, having the adult shape. The early constitution of the latter structures seems to be linked with the mechanical demands of biological functions such as breathing and feeding.     

Taste bud form and distribution on lips and in the oropharyngeal cavity of cardinal fish species (Apogonidae, Teleostei), with remarks on their dentition

The oral dentition and type and number of taste buds (TB) on the lips and in the oropharyngeal cavity were compared by means of SEM in 11 species of cardinal fishes (Apogonidae) belonging to five genera. The occurrence of a dense cover of skin papillae on the lips of some species (e.g., Apogon frenatus), as well as differences in structure of vomer, tongue, and palatinum, expose additional morphological characters important for clarification of the taxonomy of this group of fishes. Differences are also revealed in the type of dentition, such as on the vomer and epi-hypopharyngeal bones. Strong and dense dentition of the anterior part of the oral cavity and a high number of TB on this site in species feeding on larger prey (e.g., Cheilodipterus spp) is compared to the relatively feeble jaw armor and richness of TB on the more pharyngeal site in species feeding on smaller prey (e.g., Apogon angustatus, A. frenatus). In addition to the three types of TB (Types I-III) previously described from various teleost fish, a fourth type (Type IV), comprising very small buds, was found in some cardinal fish (Apogon angustatus, A. frenatus). The various TB are distributed from the lips to the pharyngeal bones, on the breathing valves, tongue, palatinum, and pharyngeal bones; their number and type on the various sites differ in the different species. In all species studied the Types I and II TB, elevated above the surrounding epithelium, dominated the lips and anterior part of mouth, while Types III and IV, which end apically at the level with the epithelium, dominated the more posterior pharyngeal region. The highest number of TB, around 24,600, were found in Fowleria variegata, a typical nocturnal species, and the lowest in the diurnal and crepuscular Apogon cyanosoma (1,660) and Cheilodipterus quinquestriatus (2,400). Differences are also revealed in the type of dentition, such as on the vomer and epi-hypopharyngeal bones. The number of TB increased with growth of the fishes. The differences in the total number of TB and their distribution in the oropharyngeal cavity in the various species indicates possible different mechanisms of foraging and food-recognition.     

中国鳐类脑颅的研究

作者解剖观察了33种,隶于4目、7亚目、15科、19属的中国鳐类脑颅的形态。研究结果认为:锯鳐目和鳐目是原始类群,它们均具吻软骨,其中圆犂头鳐科和团扇鳐科是特化类群。电鳐目亦具吻软骨,它们是特化和退化类群。在较高等的鲼目则无吻软骨。依据鳐类不同的分类阶元,其脑颅亦各具有不同的式型。     

秦岭生态保护区鱼类多样性研究

实地鱼类资源考察、检视鱼类标本以及参考鱼类分类、分布文献表明,秦岭生态保护区现有鱼类7目16科79属共141种(亚种)。物种多样性G-F指数的比较分析显示,和秦岭其他区域相比,秦岭生态保护区鱼类的物种多样性最高:区内不同水系之间相比,则汉江水系最高。利用β多样性指数和Jaccard相似性系数对秦岭生态保护区4条水系的鱼类多样性进行分析,结果显示区内鱼类分布南北差异明显;南坡的3条水系中,南洛河水系和嘉陵江水系鱼类生境相似程度较高,鱼类种、属分化、隔离程度较低,而与汉江水系的生境差异显著,鱼类种属分化、隔离程度较高。根据区内自然地理及水系特征,对水系间鱼类β多样性出现的差异进行了分析。     

Covariation of brain and skull shapes as a model to understand the role of crosstalk in development and evolution

Covariation among discrete phenotypes can arise due to selection for shared functions, and/or shared genetic and developmental underpinnings. The consequences of such phenotypic integration are far-reaching and can act to either facilitate or limit morphological variation. The vertebrate brain is known to act as an “organizer” of craniofacial development, secreting morphogens that can affect the shape of the growing neurocranium, consistent with roles for pleiotropy in brain–neurocranium covariation. Here, we test this hypothesis in cichlid fishes by first examining the degree of shape integration between the brain and the neurocranium using three-dimensional geometric morphometrics in an F₅ hybrid population, and then genetically mapping trait covariation using quantitative trait loci (QTL) analysis. We observe shape associations between the brain and the neurocranium, a pattern that holds even when we assess associations between the brain and constituent parts of the neurocranium: the rostrum and braincase. We also recover robust genetic signals for both hard- and soft-tissue traits and identify a genomic region where QTL for the brain and braincase overlap, implicating a role for pleiotropy in patterning trait covariation. Fine mapping of the overlapping genomic region identifies a candidate gene, notch1a, which is known to be involved in patterning skeletal and neural tissues during development. Taken together, these data offer a genetic hypothesis for brain–neurocranium covariation, as well as a potential mechanism by which behavioral shifts may simultaneously drive rapid change in neuroanatomy and craniofacial morphology.