许家窑人幼年个体的釉质发育缺陷

上世纪70年代在许家窑-侯家窑地点发现的人类化石对了解东亚中晚更新世过渡时期古人类的形态演化起到了重要作用。除形态特征外,针对许家窑人病理表现也开展过相关研究,其中许家窑人幼年个体前部牙齿上出现的黄色小坑被认为是患有氟斑牙病的证据,且可能代表世界范围内该牙病的最早实例。然而,经电子显微镜和显微断层扫描显示,这些黄色小坑或凹陷是釉质发育不良表现,而不是代表个体患有氟斑牙病后牙齿受咀嚼压力而产生的物理破损。同步辐射扫描显示,许家窑幼年个体前部牙齿釉质密度均匀,没有出现浅层釉质矿化减小的现象,不支持该个体因釉质矿化过程受影响而患有典型氟斑牙的结论。尽管如此,后部牙齿上大量坑状的釉质缺陷和坑状缺陷底部的加重生长线特征不排除是个体氟摄入过量而影响釉质形成的分泌期而导致的。除表面坑状釉质缺陷外,许家窑幼年个体恒齿不同部位的釉质内部出现缺失（空间结构一般为圆球状）。缺失主要集中在浅层区域,沿齿尖-齿颈方向的密集程度变化与釉质发育不良位置具有一定相关性。釉质内部缺失有时互连并与釉质表面垂直。以上特征显示釉质内部缺失是釉质形成过程受影响所致,且影响因素和发生机理可能与釉质发育不良的类似。许家窑幼年个体不同牙齿在外部釉质缺陷和内部釉质缺失密集程度上的差别可能反映的是个体在发育过程中所需应对的外界扰动因素程度不同。未来研究可对包含许家窑人化石的堆积物中以及许家窑人牙齿中的氟含量进行测定,以进一步研究许家窑人个体的生活环境中是否有过量的氟以及许家窑人是否摄入了过量氟元素,从而对许家窑人的牙齿发育缺陷机理有一个进一步的了解。     

广西化石猩猩牙齿釉质厚度研究

华南和东南亚发现大量更新世的猩猩牙齿化石。本研究应用CT扫描三维重建的技术方法研究了广西更新世化石猩猩牙齿釉质厚度,并与现生类人猿、现代人、化石类人猿以及早期人类进行比较分析。结果显示:广西猩猩同类牙齿的釉质厚度与牙齿大小相关性很小;臼齿和前臼齿釉质厚度在上下颌之间不存在显著性差异;来自广西不同地区的猩猩化石牙釉质厚度无显著差异。与早期人科成员相比,广西猩猩的牙釉质相对较薄,平均与相对釉质厚度值都明显小于南方古猿、傍人。与早期人属相比,小于直立人、尼人以及非洲和欧洲的早期人属化石。与现代人和现生灵长类相比,广西化石猩猩釉质厚度明显大于大部分猴类和非洲大猿;平均釉质厚度稍大于现生猩猩,而与现代人更为接近;相对釉质厚度小于现代人,而与现生猩猩差异不大,都属于偏厚型釉质。本文讨论了釉质厚度与系统分类演化、食性适应的相关问题,作者推测釉质厚度可能是物种的特征属性,与牙齿功能适应有密切关联。     

扫描电镜研究牙齿釉质的制样方法

<正> 釉质是动物体内最硬的组织,它被覆于几乎所有的哺乳动物牙齿冠面,由于它的硬度很高,大大提高了牙齿对食物的粉碎和咀嚼机能.多年来,人们利用各种仪器和方法对釉质的组织学结构和化学成分作了大量的分析和研究,为探讨釉质的发育,进化以及治疗牙齿疾病等方面的应用奠定了基础.扫描电镜用于牙齿微观结构的研究,扩展了人们对釉质结构的了解,越来越多的古生物学家和口腔医学专家认为釉质在动物的分类和系统发育研究中具有重要作用.扫描电镜由于其制样方法比较简单,放大倍数高、立体感强,可以直接观察样品表面结构等优点而更适合脊椎动物化石材料的研究工作.在国外,研究现生和化石脊椎动物牙齿微观结     

巨猿牙齿釉质厚度及对食性适应与系统演化的意义

步氏巨猿(Gigantopithecus blacki)是更新世时期生活于我国华南地区的一种超大型猿类, 它的体态特征和演化分类倍受关注。牙齿釉质厚度在探讨灵长类食性、环境适应以及系统演化方面具有重要意义。本文利用显微CT技术构建18颗巨猿臼齿虚拟模型, 测量其釉质厚度。将巨猿釉质厚度与现代人、现生类人猿、古人类、中新世古猿及其他现生灵长类进行比较, 从牙齿釉质厚度探讨巨猿的食性适应和系统演化问题。结果发现巨猿的实测釉质厚度是目前所有已知现生和化石灵长类中最厚的, 只有傍人、南非早期人属及奥兰诺古猿三种化石灵长类与之接近; 如果考虑不同物种牙齿与身体大小的关联因素, 相对釉质厚度指数显示巨猿属于"厚"釉质类型, 但非"超厚"类型, 低于奥兰诺古猿、傍人、南非早期人属; 巨猿与某些中新世古猿 (如原康修尔猿尼安萨种、非洲古猿)、南方古猿、东非早期人属、亚洲直立人以及现代人、现生卷尾猴的相对釉质厚度指数相近。巨猿的厚釉质特征与其食性和环境适应密切相关, 使得牙齿具有非常强的抗磨损功能, 能够适应长时间的咀嚼和研磨食物。从釉质厚度的系统演化角度推测, 厚釉质应该是人类祖先的特征性状, 巨猿有可能是早期人类支系演化过程中的一个特化旁支, 同时也不排除巨猿是从某种具有厚釉质的中新世古猿旁支平行演化而来的可能性。     

人类牙齿齿冠和齿根分离两种技术方法对牙釉质厚度测量的影响

在基于计算机断层扫描技术（CT）和虚拟图像处理技术的灵长类牙齿测量学研究中,经常需要分离三维虚拟模型的齿冠和齿根,再进行后续测量工作,如计算机辅助的生物力学分析、釉质厚度测量等。而分离齿冠和齿根这一步骤,目前有多种方法,如,1)根据齿颈线切分齿冠,或2)人工建立基底平面切分齿冠。为了评估这两种不同的处理方式对后续的牙齿测量学上的影响,本文使用三维方法测量了82例化石和现代人类下颌后部牙齿的釉质厚度,包括南方古猿、早期人属、尼安德特人和现代人。使用配对t检验对比发现,两种方法得到的釉质厚度数值上没有显著差别,但随后进行的种间比较发现,使用基底平面切分齿冠的方法比较费时,更依赖于测量者的人工操作,并且可能弱化了物种间前臼齿绝对釉质厚度的差异,造成系统误差。其原因是对于前臼齿和前部牙齿等齿颈线形状不规则的标本,基底平面难以建立或误差较大。在未来对釉质厚度的种间差异的研究中,特别对齿颈线形状不规则的标本（如人类前部牙齿及猩猩、黑猩猩的牙齿等）,本文推荐使用齿颈线分离齿冠和齿根,测量和计算齿颈线之上的釉质厚度。釉质厚度有一定的分类学、功能形态学和系统发育学意义。本文积累了一批可供未来对比研究的原始数据,并且发现尼安德特人前臼齿的相对釉质厚度显著小于现代人,这与前人利用臼齿、犬齿所做的对比研究结果相同,支持了尼安德特人拥有较薄的相对釉质厚度这一观点。     

东亚中更新世古人类下颔第二臼齿釉质-齿质连接面三维形状和釉质厚度分布

东亚中更新世古人类在头骨、下颌骨、牙齿等解剖部位表现出不同程度的形态多样性,中期成员代表为直立人,而晚期成员的演化地位具有较大争议。为进一步了解东亚中更新世古人类内部的形态变异特点和为东亚中更新世晚期古人类分类提供依据,本文使用微分同胚的表面匹配（Diffeomorphic Surface Matching, DSM）和形态测量图（Morphometric map）对下颌第二臼齿（M₂）釉质-齿质连接面的形状和齿冠侧面釉质厚度分布模式进行了量化分析。结果显示：1）东亚中更新世古人类与晚期人属成员（尼安德特人和现代人）存在较明显的形态差别;2）该时段晚期的东亚古人类相对中期直立人在侧面釉质厚度分布规律上具有独特性,并在釉质-齿质连接面的三维形状上与晚期人属成员更加接近。本文在以往对东亚中更新世古人类牙齿内外结构单个性状研究的基础上,使用三维形态测量方法进一步量化了M₂釉质-齿质连接面三维形状和侧面釉质厚度分布模式两项重要特征的变异特点,这对未来该时段同类型牙齿的形态鉴定以及解决东亚中更新世晚期古人类的分类地位具有一定意义。     

察干鼠、始壮鼠门齿釉质结构的立体分析

应用扫描电镜,观察阿尔泰察干鼠、始壮鼠门齿不同切面的釉质结构特征,通过分析得到下列结果。1．同一门齿的不同部位,其釉质形态虽有不同的表现形式,但反映釉质结构模式的两个主要特征不变,如HSB宽度和内外釉质层厚度比稳定．因此应用这些特征时,可以在不定位取样条件下比较．2．同一门齿的不同部位,内层HSB的倾斜度以及外层中放射状釉柱的倾斜度均有变化,变化范围可达0°—20°,但是,在通过门齿中心的各不同纵切面上,上述两个特征是稳定的,因此应用这些特征时,取样的定位范围要明确通过门齿的中心．3同一门齿的不同部位,其釉质层厚度、釉柱截面直径大小、釉柱形态等有变化,有时随外形的变化很大,因此应用这些特征时须要定位比较．4阿尔泰察干鼠为典型的多系结构,始壮鼠为典型的单系结构。     

禄丰古猿(Lufengpithecus lufengensis)牙齿釉质生长线与个体发育问题研究

运用扫描电子显微镜,对4枚禄丰古猿牙齿（恒齿）的釉质结构进行了观察研究。发现：禄丰古猿牙齿釉质表面有明显的釉面横纹结构;釉面横纹的密度向牙颈方向逐渐增大;观察记数了4枚牙齿的釉面横纹数,进而推算出牙冠的形成时间和年龄。与化石人科成员、现代人及现生大猿比较,禄丰古猿牙冠发育模式及时间,与南方古猿纤细种比较接近或相似,明显长于南方古猿粗壮种,有别于现生大猿。     

巨猿(Gigantopithecus blacki)牙齿釉质的超微结构

本文用扫描电镜研究了现代人牙齿和产自广西柳城县社冲村楞寨山巨猿洞,更新世早期的巨猿牙齿的超微结构。巨猿牙齿的表层釉质是Ⅰ型釉柱结构,厚度约为50－60μm,表层下牙尖中心区为Ⅰ型釉柱,其余为Ⅲa型及少量Ⅱ型釉柱结构。现代人牙表层釉质亦为Ⅰ型釉柱结构,厚度小于10μm,表层下,牙尖中心区处为Ⅰ型釉柱,其余为Ⅲa和Ⅲb型以及少量Ⅲ型釉柱。可以认为,这种差别具有分类学上的意义。此外,本文从研究方法上提出,研究釉柱横切面构造的最合适部位为牙尖部位的咬合面。     

早期哺乳动物三尖齿兽类牙齿的超微结构

本文用扫描电镜研究了中国云南禄丰盆地下禄丰组发现的以及英国威尔士晚三迭世的三尖齿兽类牙齿的超微结构.其釉质具有准釉柱结构,它们呈并行排列从釉牙质界延伸到釉质外表面.这种准釉柱结构由很多羽支状排列的磷灰石微晶组成.微晶的C轴与准釉柱的长轴形成交叉的角度大约为10-20度.早期哺乳动物牙齿釉质的准釉柱结构,很可能是从爬行动物无釉柱结构向哺乳动物真釉柱结构进化过程中的标志.     

辽宁大连晚更新世马类牙齿釉质结构的研究

大连晚更新世的马类共包括三个种类:野驴(Equus hemionus)、小型的普氏野马中国马亚种(E. przewalskyi sinensis)、大型的大连马(E. dalianensis)。从它们颊齿的釉质层微观结构、釉柱大小及釉质层的厚度分析,晚更新世的野驴和现生的野驴是十分接近的,可以归于同一个种。大连马与现在的普氏野马也比较接近,可归于同一个大的类别。然而,普氏野马中国马亚种却与现生的普氏野马有着比较显著的区别:中国马颊齿釉质层的釉柱平均直径比现生的普氏野马大得多,而釉质层的厚度又比现生的普氏野马更薄,所以,原来的分类未必合适,中国马似不应归于普氏野马,它可能代表一个比较特殊的种类。     

Enamel microstructure and molar wear in the greater galago,Otolemur crassicaudatus (mammalia,primates)

This study describes the molar enamel microstructure of the greater galago, based on SEM study of four individuals. Galago molar enamel consists primarily of radially oriented Pattern 1 prisms. However, the most superficial enamel is characterized by regions of poorly developed prisms or nonprismatic enamel, and Pattern 3 prisms can be found at depths intermediate and deep to the enamel surface. Orientations of prism long axes relative to wear surfaces differ among functionally distinct regions (cuspal facets, Phase I/II facets, and crushing basins). Consequently, orientations of enamel crystallites relative to these surfaces also differ. Because crystallites are the structural unit involved in enamel abrasion, these differences in orientation may have important effects on molar wear patterns. Crystallite orientations differ most between cuspal facets and Phase I/II facet surfaces. Cuspal facets are characterized by near surface-parallel interprismatic and surface-oblique prismatic crystallites. Previous experimental studies suggest that this arrangement is most resistant to wear when surface-normal (compressive) loads predominate. In contrast, prismatic and interprismatic crystallites intercept Phase I/II facet surfaces obliquely, an arrangement expected to resist abrasion when surface-parallel (shearing) loads predominate. Superficial enamel is preserved at most basin surfaces, indicating that these regions are subject to comparatively little abrasive wear. These results support the hypothesis that galago occlusal enamel is organized so as to resist abrasion of different functional regions, a property that may prove important in maintaining functional efficiency. However, this largely reflects constraints of occlusal topography on a microstructure typical of many mammals and thus does not appear to represent a structural innovation. © 1993 Wiley-Liss, Inc.     

Sauropod teeth from the Upper Cretaceous Bissekty Formation of Uzbekistan

The isolated adult teeth of titanosaurian sauropods from the Upper Cretaceous Bissekty Formation at Dzharakuduk, Uzbekistan, differ little in overall structure but show considerable variation in enamel sculpturing and wear patterns. The crown shape of unworn juvenile teeth ranges from lanceolate to conical. Most specimens have enamel texture resembling crumpled paper or completely smooth enamel. Longitudinal grooves along the mesial and distal edges are present on only a few tooth crowns and might be developed on both the labial and lingual sides. Among 252 worn tooth crowns there are eight variants of wear patterns, all possible combinations of 0–2 apical and 0–2 lateral wear facets. The most common is wear pattern A1L0 (one apical facet, no lateral facets; 62.7%). The next most common variant has two apical and no lateral facets (A2L0, 12.3%). These apical wear facets include the primary wear facets, which are produced by an opposing functional tooth, and secondary wear facets, which are produced by a replacing upper tooth coming into contact with the functional lower tooth at a late wear stage. The relative abundance of tooth crowns with two apical wear facets possibly suggests incipient development of a tooth battery in the Bissekty titanosaur.     

Regional morphological variations within the crayfish eye

Summary The existence of structural asymmetries has been quantitatively demonstrated in the crayfish compound eye. Variations in the size of the rhabdomes and corneal facets, as well as the size and extent of the accessory reflecting pigment cells, have been found. It was determined that the mean rhabdome diameter within a 70° arc in the dorsal quadrant of the retina is 11–19% smaller than the mean rhabdome diameter in the remaining areas of the eye. Also, the extent of the accessory reflecting pigment cells is diminished over an area corresponding generally to the dorsal region of smaller rhabdomes. Corneal facet size and shape vary over the surface of the cornea, with smaller facets occurring in the dorsal region. Both the mean rhabdome diameter and the mean corneal facet area for whole eyes increases linearly in animals ranging in size from 3.9–12 cm. The estimated number of corneal facets, and therefore the number of rhabdomes, increases from an average of 4700 in the 3–6.9 cm size range to about 6000 in 7–12 cm animals. These data indicate that structural asymmetries and various size-related parameters exist in the crayfish eye and should be considered in any quantitative analysis of this structure.Supported by a grant from the National Science Foundation (BNS 80-04587)     

Changes in orientation of attritional wear facets with implications for jaw motion in a mixed longitudinal sample of Propithecus edwardsi from Ranomafana National Park, Madagascar

In many mammalian species, the progressive wearing down of the teeth that occurs over an individual's lifetime has the potential to change dental function, jaw movements, or even feeding habits. The orientation of phase-I wear facets on molars reveals the direction of jaw movement during the power stroke of mastication. We investigated if and how molar wear facets change with increasing wear and/or age by examining a mixed longitudinal dataset of mandibular tooth molds from wild Propithecus edwardsi (N = 32 individuals, 86 samples). Measurements of the verticality of wear facets were obtained from three-dimensional digital models generated from μCT scans. Results show that verticality decreases over the lifetime of P. edwardsi, a change that implies an increasingly lateral translation of the jaw as the teeth move into occlusion. A more transverse phase-I power stroke supports the hypothesis that these animals chew to maximize longevity and functionality of their teeth, minimizing the "waste" of enamel, while maintaining sharp shearing crests. Results of this study indicate that wear facet verticality is more closely correlated with age than overall amount of tooth wear, measured as area of exposed dentin, suggesting that age-related changes in cranial morphology may be more responsible for adjustments in jaw motion over the lifetimes of Propithecus than wear-related changes inthe shape of occluding teeth. Finally, the rate of decrease in wear facet verticality with age is greater in males than in females suggesting differences in development and/or access to resources between the sexes in this species.     

Ultrastructure of enamel and dentine in extant dolphins (Cetacea: Delphinoidea and Inioidea)

Longitudinal and cross sections of teeth from 17 species of the Recent dolphins (Delphinoidea and Inioidea) were examined under scanning electron microscope to study the arrangement and ultrastructure of dental tissues with reference to phylogenetic and functional constraints. For most species, enamel had a simple bi-layered structure of radial enamel and an outer layer of prismless enamel. The outer prismless layer varied from 5 to 30 % of enamel thickness. The enamel of Burmeister’s porpoise (Phocoena spinipinnis) was entirely prismless. The prisms had an open sheath; tubules and tuft-like structures were common at the enamel-dentine junction. Cetacean dentine was characterized by irregularly distributed dentinal tubules in a relatively homogenous dentinal matrix. Radial enamel was observed in all Delphinoidea and in the franciscana (Pontoporia blainvillei), whereas the Amazon river dolphin (Inia geoffrensis) had prisms organized in Hunter–Schreger bands. HSB in enamel are regarded as a device for resisting propagation of cracks. These may occur due to increased functional demands, possibly related to the hardness of the species diet. Simplification in tooth shape and reduced biomechanical demands plausibly explain the primitive radial organization among delphinoids and Pontoporia. The HSB structure in the Amazon river dolphin, similar to those of extinct archaeocetes, seems to have secondary functional implications. However, the distribution of HSB in more-basal odontocetes is too poorly known to judge whether the HSB of Inia are a retained plesiomorphic feature or convergence.     

On the nature of the opaque and translucent enamel regions of some macropodinae (Macropus giganteus,Wallabia bicolor and Peradorcas concinna)

Summary Teeth of three macropod species, M. giganteus, W. bicolor and P. concinna, have been studied using the techniques of light microscopy, scanning- and transmission-electron microscopy and hardness measurement. Light microscope observations showed that the teeth of these species had a translucent enamel region close to the dentine and an outer opaque enamel region at the tooth's surface. These regions were not related to the presence or absence of tubules which are a characteristic feature of marsupial enamel. Hardness tests showed that the opaque enamel was softer than the translucent enamel. Scanning electron microscope observations revealed that there was no correlation between any particular prism packing or orientation and the opaque and translucent enamel regions. Transmission electron microscope observations showed that the translucent enamel region consisted of well defined prisms and well packed, lath-like crystals, whereas the opaque enamel was disrupted by voids (which ranged in size from enlarged micropores to about 2 m in diameter in extreme cases) between crystals and some randomly oriented, loosely packed crystals. This disruption within the opaque enamel region was more common at prism boundaries but pockets of disrupted enamel were also found within prisms and interprismatic regions. The opacity of the enamel was caused by scattering of light from the voids. The ultrastructure of the opaque enamel region indicated that this region was hypomineralized; hardness tests and polarized light microscope observations were consistent with these results.     

THE ULTRASTRUCTURE OF THE ENAMEL IN THE GIANT PANDA OF PLEISTOCENE

<正> Enamel ultrastructures in the molar teeth of the giant panda, including Ailuropoda microta of the Early Pleistocene, Ailuropoda melanoleuca bacont of the Middle and Late Pleistocene and a living form, Ailuropoda rnelanoleuca, have been investigated by scanning electron microscopy. Transverse and longitudinal sections of enamel were made in order co evaluate shape, size and arrangement of the prisms. The sections were etched then with 0.074 M H_3PO_4 for 30-60 sec. Our investigations have shown certain features of the enamel which allow us to recognize differences among Ailuropoda on the basis of examination of large areas of the enamel. The results are summarized below.     

Models of the geometry of the human ankle bone pulley: two series of geometric models for demonstrating the biomechanics of the ankle joint

2 series of models demonstrate the geometrical shape of the human trochlea tali. We have changed step by step the shape of the 2 flanking articular facets of the trochlea, the course of the edges of the trochlea, and the length of their radii, and so we have found a model responding to the biomechanic conditions of the trochlea tali. The convex surface of this model (corresponding to the superior articular surface, i.e. the facies superior trochleae tali) is a torse, the medial flanking facet (corresponding to the medial articular facet of the trochlea, i.e. the facies malleolaris medialis) is a flat cone, the lateral flanking facet (corresponding to the lateral articular facet of the trochlea, i.e. the facies malleolaris lateralis) is a screwed (helicoidal) face. The resulting model shows the 2 completely different phases of motion in the ankle joint: During dorsiflexion (motion setting out from the neutral position towards the final position of dorsiflexion), the internal malleolus leads the talus, whereas the external malleolus is pushed outwards by the screwed lateral articular facet of the trocheal. The trochlea is moved like a hinge. In the final position of dorsiflexion, the malleoli tightly embrace the 2 flanking facets of the trochlea, whilst an obvious cleft appears dorsally and medially between the superior articular surface of the trochlea and the tibial roof (i.e. the facies articularis inferior tibiae). During plantarflexion (motion setting out from the neutral position towards the final position of plantarflexion), the external malleolus leads the talus, whereas the medial articular facet of the trochlea withdraws from the internal malleolus. The trochlea is moved like a screw. In the final position of plantarflexion, the superior articular surface of the trochlea closely contacts the tibial roof, whilst an obvious cleft appears between the medial articular facet of the trochlea and the internal malleolus.