陶器脂肪酸揭示古人类食谱的研究进展

doi:10.16359/j.1000-3193/AAS.2024.0015

摘要/Abstract

摘要：

陶器是人类烹饪、盛放和贮藏食物的一种主要工具。残留于陶器内部、源自动植物油脂降解而形成的脂肪酸，反映了其最初的食物来源。故此，陶器脂肪酸分析成为国际生物考古界用于探索先民古食谱的主要研究方法之一。近些年来，我国学者虽已开始重视此研究领域并相继开展了一些研究，但总体上学界仍缺乏对陶器脂肪酸分析的研究方法、分析原理以及研究进展的系统介绍，尤其是在脂肪酸污染的判别上几乎无任何阐述。为此，本文阐述了脂肪酸分析的相关概念、分析原理和工作流程，着重介绍了判别脂肪酸污染的分析方法，在简要梳理脂肪酸分析的国内外发展史基础上，详细阐述了脂肪酸分析的一些重要研究进展（新分析技术和新研究方法、奶的起源与传播、生存环境和文化传统对先民生存策略的影响、作为食器的陶器之功能等），并指出了当前研究的一些不足并对如何开展后续研究进行展望。

关键词: 陶器, 脂肪酸, 指纹图谱, 生物标志物, 稳定同位素

Abstract:

Pottery is one of the important apparatuses for cooking, serving and storing foods in human society. Its porous characteristic makes it possible to trap the fatty acids degraded from animal and plant fats of foods to be preserved well within the pottery for long time even up to thousands of years. Therefore, archaeometrists have attempted to analyze fatty acids absorbed within potteries by employing many techniques such as mass spectrometer coupled with gas chromatography and compound-specific isotope ratios of mass spectrometry, to reconstruct the foods that humans processed or cooked. In China, however, there is still a lack of systematic introduction to the analytical principles and research progress of fatty acid analysis, especially in the identification of chemical contamination, although several new papers have been published in recent years. In this paper we firstly introduced the concepts, analytical principles and workflow of fatty acid analysis, highlighted the analytical methods used to identify fatty acid contamination, and briefly reviewed the history of fatty acid analysis in domestic and oversea circles. In general, the developmental process of fatty acid analysis can be divided into three stages. The first stage was during the period of 1970-1990, when the method of fatty acid analysis was set up by analytical chemists but there were only sporadic studies reported. During the second stage (1990-2007), researchers have had a deeper understanding on the degradation of fatty acids, standardized experimental workflow, and established systematic analytical principles. The revolutionary progress happens during the third stage (From 2008 to the present). In addition to the identification of plants and animals by mass spectrometry, the biomarkers to identify aquatic organisms, and compound-specific stable isotope analysis to identify the origins of dairy fats have been established. Now, fatty acid analysis has become one of the main international methods of exploring human diets in the past. We demonstrated some great progresses in recent years, including the advances in research techniques and methods that have led to more comprehensive information about foods, the reconstruction of milk transmission routes in Europe, the impact of environment and cultural tradition on subsistence, and the processing of food as a driving force in the emergence of pottery. Finally, we also pointed out some shortcomings of current research and provide an outlook for future research.

Key words: pottery, fatty acid, fingerprint, biomarker, stable isotope

中图分类号:

黄嫣, 胡耀武. 陶器脂肪酸揭示古人类食谱的研究进展[J]. 人类学学报, 2024, 43(05): 865-880.

HUANG Yan, HU Yaowu. Research progress of investigating the ancient people’s diets by analyzing fatty acid in pottery[J]. Acta Anthropologica Sinica, 2024, 43(05): 865-880.

图/表 5

图1 动物与植物的典型色谱图[23] a. 动物animal；b. 植物plant

Fig.1 Typical chromatograms of animals and plants

图2 非洲现代动物的脂肪酸碳稳定同位素比值[23] a.脂肪酸的δ13C16:0和δ13C18:0值/δ13C16:0 and δ13C18:0 values of fatty acids；b.脂肪酸的∆13C值/∆13C values of fatty acids

Fig.2 Carbon stable isotope ratios of fatty acids from African modern animals

图3 脂肪酸分析主要工作流程图注：主要依据参考文献[31]/ Mainly cite from the reference [31]TLE—总脂质Total lipid extract);BSTFA—N、O- 双（三甲硅基）三氟乙酰胺N, O-bis(trimethylsilyl)trifluoroacetamide);TMS—三甲基硅烷化衍生物Trimethylsilylation;FAME—脂肪酸甲酯Fatty acid methyl ester);GC—气相色谱Gas chromatography;GC-MS—气相色谱-质谱联用仪Gas chromatography-mass spectrometry;GC-IRMS—气相色谱-同位素比值质谱仪Gas, chromatography-isotope ratio mass spectrometry

Fig.3 Workflow chart of fatty acid analysis

图4 欧洲及周围地区含乳脂陶器的时空分布底图：标准地图服务系统《欧洲地图（审图号：GS(2023)2760号）》

Fig.4 Geographical and temporal distribution of milk fat residues in and around Europe

图5 中欧线纹陶文化中的特殊器型陶器[80,81] a.波兰库亚维亚地区出土带筛孔陶器残片a sieve fragment from Kuyavia；b.德国迪特福特地区儿童墓葬出土带喷口陶器a spouted vessel from Dietfurt

Fig.5 Special potteries in Central European of Linearbandkeramik Culture

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