化石人猿超科成员指趾骨弯曲程度与位移行为

doi:10.16359/j.1000-3193/AAS.2022.0033

摘要/Abstract

摘要：

灵长类近节指趾骨的弯曲程度被认为是树栖性和悬垂位移行为的一个重要指标。几何形态测量学—多项式曲线拟合法(GM-PCF)提供了一种更加精准的指趾骨弯曲程度的定量化指标,以剔除指趾骨大小因素之后的标准化曲线高度(NPCH)作为其弯曲程度的指标,配合指趾骨的曲线长度,可以更加全面地定量分析灵长类指趾骨弯曲程度与位移行为的对应关系。尤其是涵盖灵长类大部分位移行为方式的15个类群、328个个体、5000余件指趾骨的参考样本,基本可以满足各种化石灵长类指趾骨弯曲程度分析和位移行为方式重建的需求。本文总结了发现有完整第II-V近节指趾骨化石材料的人猿超科成员的颅后骨骼形态适应及位移行为的重建,并运用GM-PCF对这些指趾骨化石的弯曲程度进行了对比分析,以通过指趾骨弯曲程度重建人猿超科成员的位移行为适应,并可为这些人猿超科成员位移行为的完整演化图景增加新的认识。

关键词: 人猿超科, 指趾骨弯曲, 位移行为, 功能形态学, 多项式曲线拟合法, 两足行走

Abstract:

Phalangeal curvature of primates is an important indicator of arboreality and suspensory locomotion. Fourth order polynomial curve fitting on geometric morphometric landmark data (GM-PCF) provides a more precise and accurate quantitative measure of phalangeal curvature, namely normalized phalangeal curve height (NPCH), which controls for the impact of size. Coupled with phalangeal curve length (PCL), NPCH maps primate phalangeal curvature to locomotor modes more accurately. Furthermore, data on phalangeal curvature derived from a sample of 15 extant anthropoid primate taxa comprising 328 individuals and more than 5000 phalangeal specimens can be used to reconstruct the locomotor behaviors of fossil primates. In this study, the postcranial morphological adaptations and locomotor behaviors of fossil hominoids with complete II-V proximal phalanges (pedal and manual) are inferred using GM-PCF analysis of phalangeal curvature. The aim is to provide new information that can contribute to a more complete understanding of the evolution of the locomotor behavior of fossil hominoids. The results indicate that generally there are four stages in the evolution of hominoid locomotor behavior, including the generalized arboreal quadrupedalism stage of basal hominoids, the arboreal suspension stage of early hominids, the commencement of bipedalism with retention of suspension ability stage of early hominins and australopiths, and the bipedalism stage of the genus Homo. The adaptation of climbing and suspension does not follow a simple linear mode, but develops in a mosaic pattern, and occurs in different lineages of hominoids through different pathways, even multiple times until it completely disappears in the end. The manual phalangeal curvature comparable to modern humans already occurred in OH 86 from the >1.84 MaBP deposits of Olduvai, whereas the nearly contemporary Paranthropus robustus from South Africa still retained more curved manual and pedal phalanges. Homo naledi also has extraordinarily curved manual phalanges. Nevertheless, locomotor behavior needs the coordination of the whole body. The phalangeal curvature is just one line of evidence of functional morphology. When reconstructing the locomotor behavior of a certain fossil hominoid taxon, it is necessary to take not only the functional morphological feature of the whole body into consideration, but also the paleo-ecological factors. Another intriguing finding of this research is that, in hominoids, the ratio of the curve length of manual to pedal proximal phalanges is indicative of obligate or facultative bipedalism when it is larger than 1.3. In general, the more quadrupedal primates tend to have a ratio that is closer to 1, which means that their manual and pedal proximal phalanges have a similar curve length. However, Pongo is an exception, because it has a ratio of 1.03 in spite of being highly suspensory. Hylobatids and great apes other than Pongo all have a ratio larger than 1.3 and all engage in obligate or facultative bipedalism. If this is the case, the early hominin Ardipithecus ramidus, the australopiths Australopithecus afarensis and Australopithecus africanus, and Homo floresiensis should also have engaged in certain kinds of bipedalism.

Key words: hominoids, phalangeal curvature, locomotor behavior, functional morphology, GM-PCF, bipedality

中图分类号:

Q981

张颖奇, Terry HARRISON. 化石人猿超科成员指趾骨弯曲程度与位移行为[J]. 人类学学报, 2022, 41(04): 659-673.

ZHANG Yingqi, Terry HARRISON. Phalangeal curvature and locomotor behavior of fossil hominoids[J]. Acta Anthropologica Sinica, 2022, 41(04): 659-673.

图/表 5

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类群Taxon				地点Site	时代Age	标本Specimen	文献Ref.
原康修尔猿科Proconsulidae Leakey, 1963 埃肯博猿属Ekembo McNulty et al., 2015 赫塞隆埃肯博猿Ekembo heseloni(Walker et al., 1993)				Kaswanga, Rusinga, Kenya	早中新世 (18 MaBP)	KNM KPS8 PH69/131, 手;KNM KPS8 PH72, 足	[41]:Fig.15
	尼安扎埃肯博猿Ekembo nyanzae (Le Gros Clark et Leakey, 1950)			Rusinga, Kenya	早中新世 (18 MaBP)	KNM-RU 5872R, 足	[41]:Fig.15
	纳乔拉猿属Nacholapithecus Ishida et al., 1999 凯里奥氏纳乔拉猿Nacholapithecus kerioi Ishida et al., 1999			Nachola, northern Kenya	中中新世 (15 MaBP)	KNM-BG 17811, 右手第5指;KNM-BG 35250AQ, 右足第3或第4趾	[41]:Fig.13, c, bottom; d, top
人科Hominidae Gray, 1825 肯尼亚猿亚科Kenyapithecinae Andrews, 1992 谜猿属Griphopithecus Abel, 1902 阿尔潘氏谜猿Griphopithecus alpani Tekkaya, 1974				Paşalar, Turkey	中中新世	K1420, 手第3指; K1421; 手第4指; L1663, 手	[42]: Fig.3, right, left, Tab.1, Fig.4
	树猿亚科Dryopithecinae Gregory et Hellman, 1939 彼罗拉猿属Pierolapithecus Moyà-Solà et al., 2004 加泰罗尼亚彼罗拉猿Pierolapithecus catalaunicus Moyà-Solà et al., 2004			Barranc de Can Vila 1, Barcelona, Spain	中中新世 (13-12.5 MaBP)	IPS21350.14, 右手第4指;IPS21350.12, 左手第2指;IPS21350.15, 左手第5指	[43]:Fig.1, d, g, i
		西班牙猿属Hispanopithecus Villalta et Crusafont, 1944 莱伊塔尼西班牙猿Hispanopithecus laietanus Villalta et Crusafont, 1944		Can Llobateres 2, Vallès-Penedès Basin, Catalonia, Spain	晚中新世 (9.65 MaBP)	IPS18800, 手第4指; IPS18800, 手第3指	[44]:Fig.2, c; [45]:Fig.4, H
		鲁道巴尼奥猿属Rudapithecus Kretzoi, 1969 匈牙利鲁道巴尼奥猿Rudapithecus hungaricus Kretzoi, 1969		Rudabánya, northeastern Hungary	晚中新世 (10 MaBP)	RUD78, 手	[46]:Fig.2(a), first row
		天猿属Ouranopithecus Bonis et Melentis, 1977 马其顿天猿Ouranopithecus macedoniensis Bonis et Melentis, 1977		Ravin de la Pluie, Macedonia, Greece	晚中新世 (~ 9.3 MaBP)	RPl 86, 手	[12]:Fig.2, c
		山猿属Oreopithecus Gervais, 1872 班博利山猿Oreopithecus bambolii Gervais, 1872		Baccinello, Italy	晚中新世 (7.55 MaBP)	IGF 11778, 左手第5指; Bac 148, 手	[47]: Fig.7, p.107; [11]:Fig.17.3, i
		多瑙猿属Danuvius Böhme et al., 2019 古根莫斯氏多瑙猿Danuvius guggenmosi Böhme et al., 2019		Allgäu, Bavaria, Germany	晚中新世 (11.62 MaBP)	GPIT/MA/10000-13, 右手第2指	[14]: Fig.2, c
禄丰古猿属Lufengpithecus Wu, 1987
			禄丰古猿禄丰种Lufengpithecus lufengensis Xu et al., 1978	云南禄丰石灰坝庙山坡	晚中新世 (6.9-6.2 MaBP)	PA 1057, 手第3或4指	[15]:图5.1, G
			禄丰古猿蝴蝶种Lufengpithecus hudiensis Zhang et al., 1987	云南元谋雷老	晚中新世 (9-7 MaBP)	YV6103, 手	[1]
	猩猩亚科Ponginae Elliot, 1913 西瓦猿古属Sivapithecus Pilgrim, 1910 大足西瓦古猿Sivapithecus parvada Kelley, 1988			Sethi Nagri, Potwar Plateau, Pakistan	晚中新世 (10 MaBP)	GSP 19700, 左手第4指	[48]: Fig.17(d) 或[44]:Fig.2, b
人亚科Homininae Gray, 1825 人族Hominini Gray, 1825 地猿属Ardipithecus White et al., 1995 始祖地猿Ardipithecus kadabba Haile-Selassie, 2001				Middle Awash, Ethiopia	晚中新世(5.7-5.2 MaBP)	AME-VP-1/71, 足	[17]:Fig.1, b 或[49]: Fig.25.3, E
			根地猿Ardipithecus ramidus (White et al., 1994)	Middle Awash, Aramis, Ethiopia	早上新世(4.4 MaBP)	ARA-VP-6/500.043, 左手第2指;ARA-VP-6/500.030, 左手第3指;ARA-VP-6/500.069, 左手第4指;ARA-VP-6/500.094, 左足第4趾	[21]: Fig.S7, A, B, C; [22]: Fig.S10, C
		南方古猿属Australopithecus Dart, 1925 阿法尔南方古猿Australopithecus afarensis Johanson et al., 1978		Hadar, Afar, Ethiopia	上新世 (3.8-3.0 MaBP)	A.L.333w-4, A.L.333-19, A.L.333-93, A.L.333-57, A.L.333x-13a, A.L.333-63, A.L.288-1x, 手;A.L.288-1y, A.L.333-26, A.L.333-60, A.L.333-71, A.L.333-102, 足;A.L.333-115(G), 左足第2趾;A.L.333-115(H), 左足第3趾;A.L.333-115(I), 左足第4趾;A.L.333-115(J), 左足第5趾	[50]: Fig.8, A, D, E, G, H, I; [51]: Fig.14, F, G; [52]: Fig.5, d, e, f, g, m, n, o, p
			非洲南方古猿Australopithecus africanus Dart, 1925	Sterkfontein, South Africa	晚上新世—早更新世(3.0-2.0 MaBP)	StW 293, 右手第4指; StW 597, 右手第5指; StW 28, 右手第5指 ; StW 355, 足	[53]: Fig.S12, E 或[54]: Fig.9.7;[55]: Fig.3; [54]: Fig.9.7;[56]: Fig.15.7
			源泉南方古猿Australopithecus sediba Berger et al., 2010	Malapa, South Africa	早更新世(2.0 MaBP)	U.W.88-164/MH2, 右手第2指;U.W.88-120/MH2, 右手第3指;U.W.88-108/MH2, 右手第4指;U.W.88-121/MH2, 右手第5指	[53]:Fig.S12, D; [57]:Fig.15
		傍人属Paranthropus Broom, 1938 粗壮傍人Paranthropus robustus Broom, 1938		Swartkrans, South Africa	早更新世(1.8-1.5 MaBP)	SKX 5018, 手第4指;SKX 27431, 手第3指;SKX 22741, SKX 10641, SKX 15468, 手;SKX 16699, 足	[58]:Fig.3; [59]: Fig.6, (a), left; Fig.3, Tab.3; Fig.6, (a), right
		人属Homo Linnaeus, 1758 人属早期成员early Homo		Olduvai, Tanzania	早更新世(>1.84 MaBP)	OH 86, 手	[31]:Fig.2
				Sima del Elefante, Sierra de Atapuerca, Spain	早更新世(1.2 or 1.3 MaBP)	ATE9-2, 手第5指	[32]:Fig.1, D
			纳莱迪人Homo naledi Berger et al., 2015	Rising Star, South Africa	中更新世(335-236 kaBP)	U.W.101-1328, 右手第2指;U.W.101-1327, 右手第3指;U.W.101-1326, 右手第4指	[37]: Fig.7, a, b, c
			弗洛勒斯人Homo floresiensis Brown et al., 2004	Liang Bua, Flores, Indonesia	晚更新世(100-60 kaBP)	LB6/8, 手; LB1/36, LB1/37, LB1/38, 足	[60]: Fig.15, A; [8]: Fig.19, l, n, m, Tab.4

类群Taxon				地点Site	时代Age	标本Specimen	文献Ref.
原康修尔猿科Proconsulidae Leakey, 1963 埃肯博猿属Ekembo McNulty et al., 2015 赫塞隆埃肯博猿Ekembo heseloni(Walker et al., 1993)				Kaswanga, Rusinga, Kenya	早中新世 (18 MaBP)	KNM KPS8 PH69/131, 手;KNM KPS8 PH72, 足	[41]:Fig.15
	尼安扎埃肯博猿Ekembo nyanzae (Le Gros Clark et Leakey, 1950)			Rusinga, Kenya	早中新世 (18 MaBP)	KNM-RU 5872R, 足	[41]:Fig.15
	纳乔拉猿属Nacholapithecus Ishida et al., 1999 凯里奥氏纳乔拉猿Nacholapithecus kerioi Ishida et al., 1999			Nachola, northern Kenya	中中新世 (15 MaBP)	KNM-BG 17811, 右手第5指;KNM-BG 35250AQ, 右足第3或第4趾	[41]:Fig.13, c, bottom; d, top
人科Hominidae Gray, 1825 肯尼亚猿亚科Kenyapithecinae Andrews, 1992 谜猿属Griphopithecus Abel, 1902 阿尔潘氏谜猿Griphopithecus alpani Tekkaya, 1974				Paşalar, Turkey	中中新世	K1420, 手第3指; K1421; 手第4指; L1663, 手	[42]: Fig.3, right, left, Tab.1, Fig.4
	树猿亚科Dryopithecinae Gregory et Hellman, 1939 彼罗拉猿属Pierolapithecus Moyà-Solà et al., 2004 加泰罗尼亚彼罗拉猿Pierolapithecus catalaunicus Moyà-Solà et al., 2004			Barranc de Can Vila 1, Barcelona, Spain	中中新世 (13-12.5 MaBP)	IPS21350.14, 右手第4指;IPS21350.12, 左手第2指;IPS21350.15, 左手第5指	[43]:Fig.1, d, g, i
		西班牙猿属Hispanopithecus Villalta et Crusafont, 1944 莱伊塔尼西班牙猿Hispanopithecus laietanus Villalta et Crusafont, 1944		Can Llobateres 2, Vallès-Penedès Basin, Catalonia, Spain	晚中新世 (9.65 MaBP)	IPS18800, 手第4指; IPS18800, 手第3指	[44]:Fig.2, c; [45]:Fig.4, H
		鲁道巴尼奥猿属Rudapithecus Kretzoi, 1969 匈牙利鲁道巴尼奥猿Rudapithecus hungaricus Kretzoi, 1969		Rudabánya, northeastern Hungary	晚中新世 (10 MaBP)	RUD78, 手	[46]:Fig.2(a), first row
		天猿属Ouranopithecus Bonis et Melentis, 1977 马其顿天猿Ouranopithecus macedoniensis Bonis et Melentis, 1977		Ravin de la Pluie, Macedonia, Greece	晚中新世 (~ 9.3 MaBP)	RPl 86, 手	[12]:Fig.2, c
		山猿属Oreopithecus Gervais, 1872 班博利山猿Oreopithecus bambolii Gervais, 1872		Baccinello, Italy	晚中新世 (7.55 MaBP)	IGF 11778, 左手第5指; Bac 148, 手	[47]: Fig.7, p.107; [11]:Fig.17.3, i
		多瑙猿属Danuvius Böhme et al., 2019 古根莫斯氏多瑙猿Danuvius guggenmosi Böhme et al., 2019		Allgäu, Bavaria, Germany	晚中新世 (11.62 MaBP)	GPIT/MA/10000-13, 右手第2指	[14]: Fig.2, c
禄丰古猿属Lufengpithecus Wu, 1987
			禄丰古猿禄丰种Lufengpithecus lufengensis Xu et al., 1978	云南禄丰石灰坝庙山坡	晚中新世 (6.9-6.2 MaBP)	PA 1057, 手第3或4指	[15]:图5.1, G
			禄丰古猿蝴蝶种Lufengpithecus hudiensis Zhang et al., 1987	云南元谋雷老	晚中新世 (9-7 MaBP)	YV6103, 手	[1]
	猩猩亚科Ponginae Elliot, 1913 西瓦猿古属Sivapithecus Pilgrim, 1910 大足西瓦古猿Sivapithecus parvada Kelley, 1988			Sethi Nagri, Potwar Plateau, Pakistan	晚中新世 (10 MaBP)	GSP 19700, 左手第4指	[48]: Fig.17(d) 或[44]:Fig.2, b
人亚科Homininae Gray, 1825 人族Hominini Gray, 1825 地猿属Ardipithecus White et al., 1995 始祖地猿Ardipithecus kadabba Haile-Selassie, 2001				Middle Awash, Ethiopia	晚中新世(5.7-5.2 MaBP)	AME-VP-1/71, 足	[17]:Fig.1, b 或[49]: Fig.25.3, E
			根地猿Ardipithecus ramidus (White et al., 1994)	Middle Awash, Aramis, Ethiopia	早上新世(4.4 MaBP)	ARA-VP-6/500.043, 左手第2指;ARA-VP-6/500.030, 左手第3指;ARA-VP-6/500.069, 左手第4指;ARA-VP-6/500.094, 左足第4趾	[21]: Fig.S7, A, B, C; [22]: Fig.S10, C
		南方古猿属Australopithecus Dart, 1925 阿法尔南方古猿Australopithecus afarensis Johanson et al., 1978		Hadar, Afar, Ethiopia	上新世 (3.8-3.0 MaBP)	A.L.333w-4, A.L.333-19, A.L.333-93, A.L.333-57, A.L.333x-13a, A.L.333-63, A.L.288-1x, 手;A.L.288-1y, A.L.333-26, A.L.333-60, A.L.333-71, A.L.333-102, 足;A.L.333-115(G), 左足第2趾;A.L.333-115(H), 左足第3趾;A.L.333-115(I), 左足第4趾;A.L.333-115(J), 左足第5趾	[50]: Fig.8, A, D, E, G, H, I; [51]: Fig.14, F, G; [52]: Fig.5, d, e, f, g, m, n, o, p
			非洲南方古猿Australopithecus africanus Dart, 1925	Sterkfontein, South Africa	晚上新世—早更新世(3.0-2.0 MaBP)	StW 293, 右手第4指; StW 597, 右手第5指; StW 28, 右手第5指 ; StW 355, 足	[53]: Fig.S12, E 或[54]: Fig.9.7;[55]: Fig.3; [54]: Fig.9.7;[56]: Fig.15.7
			源泉南方古猿Australopithecus sediba Berger et al., 2010	Malapa, South Africa	早更新世(2.0 MaBP)	U.W.88-164/MH2, 右手第2指;U.W.88-120/MH2, 右手第3指;U.W.88-108/MH2, 右手第4指;U.W.88-121/MH2, 右手第5指	[53]:Fig.S12, D; [57]:Fig.15
		傍人属Paranthropus Broom, 1938 粗壮傍人Paranthropus robustus Broom, 1938		Swartkrans, South Africa	早更新世(1.8-1.5 MaBP)	SKX 5018, 手第4指;SKX 27431, 手第3指;SKX 22741, SKX 10641, SKX 15468, 手;SKX 16699, 足	[58]:Fig.3; [59]: Fig.6, (a), left; Fig.3, Tab.3; Fig.6, (a), right
		人属Homo Linnaeus, 1758 人属早期成员early Homo		Olduvai, Tanzania	早更新世(>1.84 MaBP)	OH 86, 手	[31]:Fig.2
				Sima del Elefante, Sierra de Atapuerca, Spain	早更新世(1.2 or 1.3 MaBP)	ATE9-2, 手第5指	[32]:Fig.1, D
			纳莱迪人Homo naledi Berger et al., 2015	Rising Star, South Africa	中更新世(335-236 kaBP)	U.W.101-1328, 右手第2指;U.W.101-1327, 右手第3指;U.W.101-1326, 右手第4指	[37]: Fig.7, a, b, c
			弗洛勒斯人Homo floresiensis Brown et al., 2004	Liang Bua, Flores, Indonesia	晚更新世(100-60 kaBP)	LB6/8, 手; LB1/36, LB1/37, LB1/38, 足	[60]: Fig.15, A; [8]: Fig.19, l, n, m, Tab.4

类群 Taxon	曲线长度(PCL, mm)									标准化曲线高度(NPCH)
	指骨 Manual				趾骨 Pedal				均比 Ratio	指骨 Manual				趾骨 Pedal				均比 Ratio
	Min	Avg	Max	n	Min	Avg	Max	n	均比 Ratio	Min	Avg	Max	n	Min	Avg	Max	n	均比 Ratio
Ateles	26.84	33.12	37.38	40	25.07	28.61	31.50	32	1.16	0.10	0.15	0.20	40	0.09	0.13	0.17	32	1.15
Alouatta	20.86	23.67	27.54	8	21.09	24.78	28.06	8	0.96	0.09	0.12	0.16	8	0.08	0.13	0.18	8	0.92
Cebus	12.53	16.42	20.32	48	12.92	16.81	20.04	48	0.98	0.02	0.05	0.09	48	0.02	0.05	0.08	48	1.00
Macaca	13.84	19.12	26.13	140	14.50	20.42	27.44	140	0.94	0.03	0.10	0.17	140	0.04	0.08	0.13	140	1.25
Papio	14.16	18.84	25.42	24	14.49	19.79	27.01	24	0.95	0.03	0.06	0.10	24	0.03	0.06	0.09	24	1.00
Colobus	24.16	27.22	30.49	4	20.99	25.57	29.07	4	1.06	0.11	0.12	0.13	4	0.07	0.09	0.11	4	1.33
Semnopithecus	17.89	22.13	29.22	11	17.54	23.48	29.57	11	0.94	0.10	0.12	0.15	11	0.05	0.08	0.11	11	1.50
Trachypithecus	16.43	23.45	28.76	28	15.72	22.59	27.13	32	1.04	0.06	0.12	0.17	28	0.03	0.09	0.15	32	1.33
Presbytis	21.13	25.14	28.42	16	20.28	23.70	27.32	18	1.06	0.06	0.10	0.13	16	0.04	0.08	0.11	18	1.25
Hylobatidae	20.70	34.79	51.79	222	11.12	23.67	35.07	192	1.47	0.09	0.16	0.23	222	0.02	0.10	0.20	192	1.60
Pongo	42.93	60.79	83.41	163	38.78	58.94	78.57	156	1.03	0.09	0.21	0.34	162	0.13	0.29	0.43	156	0.72
Gorilla	30.92	45.57	58.76	122	24.56	33.72	43.53	115	1.35	0.05	0.09	0.16	122	0.00	0.09	0.21	115	1.00
Pan	32.09	46.42	63.07	160	22.89	34.04	44.81	170	1.36	0.04	0.12	0.20	160	0.04	0.14	0.24	170	0.86
Homo sapiens	18.92	32.11	48.53	268	12.32	21.13	25.85	267	1.52	-0.02	0.05	0.10	268	-0.12	0.00	0.12	267	N.A.
Ekembo heseloni		27.86		1		25.85		1	1.08		0.13		1		0.08		1	1.63
Nacholapithecus kerioi		29.70		1		34.97		1	0.85		0.10		1		0.11		1	0.91
Ardipithecus ramidus	39.27	41.95	46.34	3		27.09		1	1.55	0.15	0.17	0.19	3		0.17		1	1.00
Aus. afarensis	30.98	35.72	42.11	7	19.20	27.20	45.00	9	1.31	0.10	0.14	0.18	7	0.05	0.14	0.24	9	1.00
Aus. africanus	25.29	27.68	29.18	3		19.93		1	1.39	0.10	0.11	0.12	3		0.17		1	0.65
Paranthropus robustus	25.21	26.45	29.05	5		25.50		1	1.04	0.06	0.10	0.12	5		0.06		1	1.67
Homo floresiensis		28.22		1	19.42	19.52	19.63	3	1.45		0.07		1	0.08	0.09	0.10	3	0.78

类群 Taxon	曲线长度(PCL, mm)									标准化曲线高度(NPCH)
	指骨 Manual				趾骨 Pedal				均比 Ratio	指骨 Manual				趾骨 Pedal				均比 Ratio
	Min	Avg	Max	n	Min	Avg	Max	n	均比 Ratio	Min	Avg	Max	n	Min	Avg	Max	n	均比 Ratio
Ateles	26.84	33.12	37.38	40	25.07	28.61	31.50	32	1.16	0.10	0.15	0.20	40	0.09	0.13	0.17	32	1.15
Alouatta	20.86	23.67	27.54	8	21.09	24.78	28.06	8	0.96	0.09	0.12	0.16	8	0.08	0.13	0.18	8	0.92
Cebus	12.53	16.42	20.32	48	12.92	16.81	20.04	48	0.98	0.02	0.05	0.09	48	0.02	0.05	0.08	48	1.00
Macaca	13.84	19.12	26.13	140	14.50	20.42	27.44	140	0.94	0.03	0.10	0.17	140	0.04	0.08	0.13	140	1.25
Papio	14.16	18.84	25.42	24	14.49	19.79	27.01	24	0.95	0.03	0.06	0.10	24	0.03	0.06	0.09	24	1.00
Colobus	24.16	27.22	30.49	4	20.99	25.57	29.07	4	1.06	0.11	0.12	0.13	4	0.07	0.09	0.11	4	1.33
Semnopithecus	17.89	22.13	29.22	11	17.54	23.48	29.57	11	0.94	0.10	0.12	0.15	11	0.05	0.08	0.11	11	1.50
Trachypithecus	16.43	23.45	28.76	28	15.72	22.59	27.13	32	1.04	0.06	0.12	0.17	28	0.03	0.09	0.15	32	1.33
Presbytis	21.13	25.14	28.42	16	20.28	23.70	27.32	18	1.06	0.06	0.10	0.13	16	0.04	0.08	0.11	18	1.25
Hylobatidae	20.70	34.79	51.79	222	11.12	23.67	35.07	192	1.47	0.09	0.16	0.23	222	0.02	0.10	0.20	192	1.60
Pongo	42.93	60.79	83.41	163	38.78	58.94	78.57	156	1.03	0.09	0.21	0.34	162	0.13	0.29	0.43	156	0.72
Gorilla	30.92	45.57	58.76	122	24.56	33.72	43.53	115	1.35	0.05	0.09	0.16	122	0.00	0.09	0.21	115	1.00
Pan	32.09	46.42	63.07	160	22.89	34.04	44.81	170	1.36	0.04	0.12	0.20	160	0.04	0.14	0.24	170	0.86
Homo sapiens	18.92	32.11	48.53	268	12.32	21.13	25.85	267	1.52	-0.02	0.05	0.10	268	-0.12	0.00	0.12	267	N.A.
Ekembo heseloni		27.86		1		25.85		1	1.08		0.13		1		0.08		1	1.63
Nacholapithecus kerioi		29.70		1		34.97		1	0.85		0.10		1		0.11		1	0.91
Ardipithecus ramidus	39.27	41.95	46.34	3		27.09		1	1.55	0.15	0.17	0.19	3		0.17		1	1.00
Aus. afarensis	30.98	35.72	42.11	7	19.20	27.20	45.00	9	1.31	0.10	0.14	0.18	7	0.05	0.14	0.24	9	1.00
Aus. africanus	25.29	27.68	29.18	3		19.93		1	1.39	0.10	0.11	0.12	3		0.17		1	0.65
Paranthropus robustus	25.21	26.45	29.05	5		25.50		1	1.04	0.06	0.10	0.12	5		0.06		1	1.67
Homo floresiensis		28.22		1	19.42	19.52	19.63	3	1.45		0.07		1	0.08	0.09	0.10	3	0.78