Three-dimensional enamel thickness and bite force of Rudapithecus hungaricus and implications for its dietary adaptation

doi:10.16359/j.1000-3193/AAS.2025.0117

Abstract

Abstract:

Rudapithecus hungaricus, a late Miocene great ape from Rudabánya, Hungary, is a key taxon for understanding the origin, evolution, and dispersal of Homininae. This species has been hypothesized to be capable of processing hard food items. To test this hypothesis, we conducted three-dimensional analyses of enamel thickness (ET) across eight Rudapithecus teeth (including four premolars and four molars) and estimated bite force (BF) of four molars using μCT data. Two enamel thickness indices were measured: Three-dimensional average enamel thickness (3DAET) and the ratio of enamel-thickness to dentine-thickness (3DRED). According to Chai (2018), we measured dentine horn angle (DHA) and cuspal enamel thickness (CET) to estimate BF. Then we compared the results with that of extant great apes (Pan, Gorilla, and Pongo), including 61 ET measurements and 18 BF estimates. Results reveal that the average ET of Rudapithecus is greater in molars than in premolars. While Rudapithecus is broadly akin to Pan with respect to premolar ET, its molar ET shows a pattern more similar to Pongo. Furthermore, the average molar BF of Rudapithecus is 469.66N, which is larger than that of Pan (353.56 N), smaller than that of Gorilla (1023.06 N), and approximately equal to Pongo (499.62 N). Considering a high similarity between Rudapithecus and Pongo regarding molar ET and molar BF, and previous studies have shown that Pongo can process both tough and hard foods, thus our results support the hypothesis that Rudapithecus had the capability of processing hard foods. However, our results do not necessarily suggest that Rudapithecus had an overall tougher and/or harder diet. Which foods a species have actually eaten depends on a variety of factors such as the food processing capabilities, environmental variability, the accessibility of preferred foods, and the competition with other species. Combined with previous dietary researches, it is possible that the functional significance of thick enamel and great molar BF presented in Rudapithecus is to ensure basic energy intake by processing infrequently-exploited exigent mechanically challenging foods (hard and/or tough foods) during periods of fruit scarcity. To advance the understanding of Rudapithecus feeding ecology, future researches may need to incorporate direct dietary evidence derived from various methods such as phytolith, calcium isotope, and dental chipping analyses.

Key words: Rudapithecus hungaricus, 3D enamel thickness, bite force, fallback food

CLC Number:

Q981

MENG Ziyang, YANG Yuwei, LIAO Wei, WANG Wei, YI Zhixing. Three-dimensional enamel thickness and bite force of Rudapithecus hungaricus and implications for its dietary adaptation[J]. Acta Anthropologica Sinica, 2026, 45(02): 258-267.

Figures/Tables 6

References 49

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指标Index	属种Taxon	p3	p4	m1	m2	m3	合计Total	参考文献References
三维釉质厚度3D ET	鲁道古猿 R. hungaricus	2	2	2	2	0	8	本文研究材料
	黑猩猩 P. troglodytes	5	5	10	9	0	29	[31,35,36,38-40]
	大猩猩 G. Gorilla	5	4	4	4	0	17	[35,38,39]
	猩猩 Pongo sp.	0	0	6	9	0	15	[37,40]
咬合力BF	鲁道古猿 R. hungaricus	0	0	2	2	0	4	本文研究材料
	黑猩猩 P. troglodytes	0	0	2	2	0	4	[29,41]
	大猩猩 G. Gorilla	0	0	0	2	3	5	[29]
	猩猩 Pongo sp.	0	0	1	6	2	9	[29]

指标Index	属种Taxon	p3	p4	m1	m2	m3	合计Total	参考文献References
三维釉质厚度3D ET	鲁道古猿 R. hungaricus	2	2	2	2	0	8	本文研究材料
	黑猩猩 P. troglodytes	5	5	10	9	0	29	[31,35,36,38-40]
	大猩猩 G. Gorilla	5	4	4	4	0	17	[35,38,39]
	猩猩 Pongo sp.	0	0	6	9	0	15	[37,40]
咬合力BF	鲁道古猿 R. hungaricus	0	0	2	2	0	4	本文研究材料
	黑猩猩 P. troglodytes	0	0	2	2	0	4	[29,41]
	大猩猩 G. Gorilla	0	0	0	2	3	5	[29]
	猩猩 Pongo sp.	0	0	1	6	2	9	[29]

齿位Tooth	数量n	属种Taxon	V_e (mm³)		A_EDJ (mm²)		V_d (mm³)		3DAET (mm)		3DRED
齿位Tooth	数量n	属种Taxon	平均值Mean	标准差SD	平均值Mean	标准差SD	平均值Mean	标准差SD	平均值Mean	标准差SD	平均值Mean	标准差SD
p3	2	鲁道古猿 R. hungaricus	114.16	1.91	203.56	0.58	278.81	0.62	0.56	0.01	7.42	0.04
	5	黑猩猩 P. troglodytes	101.85	24.28	158.14	2.47	192.93	16.18	0.65	0.15	8.05	0.81
	5	大猩猩 G. gorilla	188.20	36.58	272.04	49.24	469.61	146.58	0.69	0.02	7.43	0.23
p4	2	鲁道古猿 R. hungaricus	118.00	0.48	156.41	3.37	212.50	24.55	0.75	0.02	8.24	0.33
	5	黑猩猩 P. troglodytes	96.44	7.45	138.01	3.36	164.37	19.36	0.70	0.06	8.40	0.51
	5	大猩猩 G. gorilla	228.79	34.74	251.12	21.71	383.23	54.52	0.90	0.06	8.42	0.09
m1	2	鲁道古猿 R. hungaricus	179.12	0.98	183.01	0.39	238.85	0.92	0.98	0.01	9.08	0.03
	6	黑猩猩 P. troglodytes	120.52	21.24	174.16	22.72	247.84	39.46	0.69	0.07	7.86	0.28
	4	大猩猩 G. gorilla	295.93	29.85	352.22	26.70	855.23	36.75	0.84	0.12	7.02	0.23
	10	猩猩Pongo sp.	195.98	25.11	231.90	31.62	335.59	40.88	0.85	0.10	8.36	0.45
m2	2	鲁道古猿 R. hungaricus	258.68	1.87	223.41	0.64	334.06	3.91	1.16	0.01	9.18	0.01
	9	黑猩猩 P. troglodytes	149.86	23.82	199.00	37.00	287.95	55.75	0.76	0.05	8.06	0.18
	4	大猩猩 G. gorilla	429.54	95.57	404.18	43.62	1209.21	121.58	1.05	0.16	7.04	0.35
	9	猩猩Pongo sp.	238.49	26.46	253.19	57.91	384.25	84.40	0.97	0.17	8.58	0.35

齿位Tooth	数量n	属种Taxon	V_e (mm³)		A_EDJ (mm²)		V_d (mm³)		3DAET (mm)		3DRED
齿位Tooth	数量n	属种Taxon	平均值Mean	标准差SD	平均值Mean	标准差SD	平均值Mean	标准差SD	平均值Mean	标准差SD	平均值Mean	标准差SD
p3	2	鲁道古猿 R. hungaricus	114.16	1.91	203.56	0.58	278.81	0.62	0.56	0.01	7.42	0.04
	5	黑猩猩 P. troglodytes	101.85	24.28	158.14	2.47	192.93	16.18	0.65	0.15	8.05	0.81
	5	大猩猩 G. gorilla	188.20	36.58	272.04	49.24	469.61	146.58	0.69	0.02	7.43	0.23
p4	2	鲁道古猿 R. hungaricus	118.00	0.48	156.41	3.37	212.50	24.55	0.75	0.02	8.24	0.33
	5	黑猩猩 P. troglodytes	96.44	7.45	138.01	3.36	164.37	19.36	0.70	0.06	8.40	0.51
	5	大猩猩 G. gorilla	228.79	34.74	251.12	21.71	383.23	54.52	0.90	0.06	8.42	0.09
m1	2	鲁道古猿 R. hungaricus	179.12	0.98	183.01	0.39	238.85	0.92	0.98	0.01	9.08	0.03
	6	黑猩猩 P. troglodytes	120.52	21.24	174.16	22.72	247.84	39.46	0.69	0.07	7.86	0.28
	4	大猩猩 G. gorilla	295.93	29.85	352.22	26.70	855.23	36.75	0.84	0.12	7.02	0.23
	10	猩猩Pongo sp.	195.98	25.11	231.90	31.62	335.59	40.88	0.85	0.10	8.36	0.45
m2	2	鲁道古猿 R. hungaricus	258.68	1.87	223.41	0.64	334.06	3.91	1.16	0.01	9.18	0.01
	9	黑猩猩 P. troglodytes	149.86	23.82	199.00	37.00	287.95	55.75	0.76	0.05	8.06	0.18
	4	大猩猩 G. gorilla	429.54	95.57	404.18	43.62	1209.21	121.58	1.05	0.16	7.04	0.35
	9	猩猩Pongo sp.	238.49	26.46	253.19	57.91	384.25	84.40	0.97	0.17	8.58	0.35