Methods for estimating cranial capacity from Chinese human fossils

  • Xiujie WU ,
  • Wei ZHANG
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  • 1. Key Laboratory of Vertebrate Evolution and Human Origin of Chinese Academy of Sciences, Institute of Vertebrate Paleontology and Paleoanthropology, Chinese Academy of Sciences, Beijing 100044
    2. CAS Center for Excellence in Life and Paleoenvironment, Beijing 100044

Received date: 2019-06-04

  Revised date: 2019-07-03

  Online published: 2020-09-10

Abstract

Ancient human skulls exhibit anatomical and morphological differences from modern skulls that depend on the evolutionary stage of the fossil under study. Thus, formulae derived using modern human skull measurements are mostly unsuitable for calculating cranial capacities from ancient human fossils. The most accurate way to estimate cranial capacities of human fossil skulls is through internal cranial vault reconstructions; However, due to the complex reconstruction process of endocranial casts, as well as the rare and almost never fully intact fossil skulls, prompting an intense search by paleoanthropologists for better methods for estimating ancient human values. Here, cranial capacity methods for their estimation from Chinese human fossils were compared and analyzed, with the following results: 1) Anatomical features of early modern humans and modern humans are basically similar. Thus, the regression equation derived using modern human skull measurements to estimate cranial capacity applies to early modern human fossils; 2) Homo erectus’ thick skull and low cranium differ markedly from corresponding modern human features. Therefore, instead of the modern human formula, the regression equation derived here from Chinese Homo erectus skull measurements, C=-1301.944+60606L+0.718b+9.936h, should be used to calculate Homo erectus cranial capacity. Using this formula, the cranial capacity of the Lantian Homo erectus was estimated to be 918 mL, as compared to the previous estimate of 778 mL; 3) Physical features of archaic Homo sapiens, which lie somewhere between those of Homo erectus and early modern humans, vary markedly from these extremes; therefore their cranial capacities cannot be estimated using a single formula. For example, cranial capacities of archaic human fossils Dali and Hualongdong 6, which exhibit physical characteristics more closely resembling those of Homo erectus than those of early modern humans, are best calculated using the Homo erectus formula. Conversely, cranial capacities of archaic human fossils possessing physical characteristics closer to early modern humans than to Homo erectus, such as Xuchang 1, should be estimated using the modern human formula. In yet a third scenario, cranial capacities of fossils exhibiting physical characteristics between those of Homo erectus and early modern humans, such as Maba and Jinniushan, should be calculated using averages of values obtained using both modern human and Homo erectus formulae.

Cite this article

Xiujie WU , Wei ZHANG . Methods for estimating cranial capacity from Chinese human fossils[J]. Acta Anthropologica Sinica, 2019 , 38(04) : 513 -524 . DOI: 10.16359/j.cnki.cn11-1963/q.2019.0061

References

[1] 吴秀杰, 张玄. 中国古人类颅内模及脑演化研究进展[J]. 人类学学报, 2018,37(3):371-383
[2] Manjunath KY. Estimation of cranial volume-an overview of methodologies[J]. Journal of the Anatomical Society of India, 2002,51:85-91
[3] Lee A, Pearson K. Data for the problem of evolution in man-a first study of the correlation of the human skull[J]. Philosophical Transactions of Royal Society, London, 1901,196a:225-264
[4] Woo TL. Formulae for the determination of the capacity of the Chinese skulls from external measurements[J]. Anthropology Journal Institute History Philology Sinica, 1942,2:1-14
[5] Stewart TD. Cranial capacity studies[J]. American Journal of Physical Anthropology, 1934,XVIII(3):337-361
[6] Uspenskii S. A new method for measuring cranial capacity[J]. American Journal of Physical Anthropology, 1954,22:115-117
[7] MacKinnon IL. The relation of the capacity of the human skull to its roentgenological length[J]. American Journal of Roentgenology, Radium therapy and Nuclear Medicine, 1955,14(6):1026-1029
[8] Mayhew TM, Olsen DR. Magnetic resonance imaging (MRI) and model-fore brain estimates of forebrain volume determined using the Cavalieri principle[J]. Journal of Anatomy, 1991,178:133-144
[9] Conroy GC, Vannier MW. Noninvasive three-dimensional computer imaging of matrix-filled fossil skulls by high-resolution computed tomography[J]. Science, 1984,26:456-458
[10] Shipman P, Storm P. Missing Links: Euge`ne Dubois and the origins of Paleoanthropology[J]. Evolutionary Anthropolology, 2002,11:108-116
[11] Dart R. Australopithecus africanus. The man-ape of South Africa[J]. Nature, 1925,115:195-199
[12] 吴秀杰, 刘武, Schepartz L. 周口店直立人颅内模的复原与研究[J]. 人类学学报, 2004,23(增刊):22-34
[13] Leakey LSB, Tobias PV, Napier JR. A new species of the genus Homo from Olduvai Gorge[J]. Nature, 1964,202:7-9
[14] Zhang YM, Wu XJ, Schepartz L. Comparing methods for estimating cranial capacity in incomplete human fossils using the Jingchuan 1 partial cranium as an example[J]. Quanternary International, 2017,434:57-64
[15] 吴秀杰, 刘武, 董为, 等. 柳江人头骨化石的CT扫描与脑形态特征[J]. 科学通报, 2008,53(13):1570-1575
[16] 丁士海, 阎锡光, 法德华, 等. 颅容量的测量与推算的改进[J]. 人类学学报, 1992,11(3):241-249
[17] Oliver G, Dricot JM. Estimation of the cranial capacity of fossil hominids[A]. In: Tuttle RH ed. Primate Functional Morphology and Evolution. Paris: Mouton Publishers, 1975, 443-464
[18] 吴汝康. 广西柳江发现的人类化石[J]. 古脊椎动物与古人类, 1959,1:97-104
[19] 吴新智. 周口店山顶洞人化石的研究[J]. 古脊椎动物与古人类, 1961,3:181-203
[20] 裴文中, 吴汝康. 资阳人[M]. 中国科学院古脊椎动物与古人类研究所甲种专刊, 1957, 第1号: 1-71
[21] 李海军, 吴秀杰, 李盛华, 等. 甘肃泾川更新世晚期人类头骨的研究[J]. 科学通报, 2009,54(21):3357-3363
[22] Black D. The brain cast of Sinanthropus-A Review[J]. Journal of comparative neurology, 1932,56:361-366
[23] Weidenreich F. Observations on the form and proportions of the endocranial casts of Sinanthropus pekinensis and the great apes: A comparative study of brain size[M]. Palaeontologia Sinica Series D, 1936,7:1-50
[24] 邱中郎, 顾玉珉, 张银运, 等. 周口店新发现的北京猿人化石及其文化遗物[J]. 古脊椎动物与古人类, 1973,11:109-131
[25] Wu XJ, Holloway R, Schepartz L, et al. A New brain endocast of Homo erectus from Hulu Cave, Nanjing, China[J]. American Journal of Physical Anthropology, 2011,145:452-460
[26] 李天元, 艾美利, 廖美炎, 等. 郧县人头骨化石三维复原的初步研究[J]. 人类学学报, 2004,4(增刊):12-21
[27] 吴汝康, 董兴仁. 安徽和县猿人化石的初步研究[J]. 人类学学报, 1982,1:2-13
[28] 吴汝康. 蓝田猿人头骨的特征及其在人类进化系统上的地位[J]. 科学通报, 1965,6:488-493
[29] 吴新智. 陕西大荔县发现的早期智人古老类型的一个完好头骨[J]. 中国科学, 1981,2:200-206
[30] 吴汝康. 辽宁营口金牛山人化石头骨的复原及其主要性状[J]. 人类学学报, 1988,7:97-101
[31] Wu XJ, Bruner E. The Endocranial Anatomy of Maba 1[J]. American Journal of Physical Anthropology, 2016,160(4):633-643
[32] Li ZY, Wu XJ, Zhou LP, et al. Late Pleistocene archaic human crania from Xuchang, China[J]. Science, 2017,355(6328):969-972
[33] Wu XJ, Pei SW, Cai YJ, et al. Archaic human remains from Hualongdong, China, and Middle Pleistocene human continuity and variation[J]. Proceedings of the National Academy of Sciences the United States of America, 2019,116:9820-9824
[34] 吴汝康, 彭如策. 广东韶关马坝发现的早期古人类型人类化石[J]. 古脊椎动物学报, 1959,3:176-182
[35] 张银运, 刘武. 南京汤山直立人脑容量的推算[J]. 人类学学报, 2003,22:201-205
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