Hostname: page-component-7c8c6479df-8mjnm Total loading time: 0 Render date: 2024-03-29T05:56:19.475Z Has data issue: false hasContentIssue false

Reconstructing Middle Horizon Camelid Diets and Foddering Practices: Microbotanical and Isotope Analyses of Dental Remains from Quilcapampa, Peru

Published online by Cambridge University Press:  23 January 2023

Mallory A. Melton*
Affiliation:
Pre-Columbian Studies, Dumbarton Oaks, Washington, DC, USA
Aleksa K. Alaica
Affiliation:
Department of Anthropology, University of British Columbia, Vancouver, British Columbia, Canada
Matthew E. Biwer
Affiliation:
Department of Anthropology and Archaeology, Dickinson College, Carlisle, PA, USA
Luis Manuel González La Rosa
Affiliation:
Archaeology Centre, University of Toronto, Ontario, Canada
Gwyneth Gordon
Affiliation:
Knowledge Enterprise, Arizona State University, Tempe, AZ, USA
Kelly J. Knudson
Affiliation:
Center for Bioarchaeological Research, School of Human Evolution and Social Change, Arizona State University, Tempe, AZ, USA
Amber M. VanDerwarker
Affiliation:
Department of Anthropology, University of California, Santa Barbara, CA, USA
Justin Jennings
Affiliation:
Department of Art and Culture, Royal Ontario Museum, Toronto, Ontario, Canada, and Department of Anthropology, University of Toronto, Ontario, Canada
*
Corresponding autor: Mallory A. Melton. Email: meltonm01@doaks.org
Rights & Permissions [Opens in a new window]

Abstract

This study uses isotope and microbotanical data from the analysis of teeth and dental calculus to investigate camelid diet and foddering practices at Quilcapampa (AD 835–900). By providing taxonomically specific evidence of foods consumed, botanical data from dental calculus complement the more general impressions of photosynthetic pathways obtained through isotopic analysis. Results suggest that the camelid diet incorporated maize (Zea mays), algarrobo (Prosopis sp.), potato chuño (Solanum sp.), and other resources. The life-history profile of one camelid (Individual 3) reveals dietary change from mainly C3 plants to more C4 plant contributions as the animal aged. This pattern is supported by carbonate isotope results indicating that this individual spent its youth in the mid-valley ecozone before becoming more mobile later in life. As this life-history example shows, isotopic and microbotanical analyses are complementary approaches, clarifying a pattern of seasonal transhumance that linked the lives of humans and animals along the Middle Horizon (AD 600–1000) caravan networks that crisscrossed the central Andes.

Resumen

Resumen

Este estudio emplea datos isotópicos y microbotánicos obtenidos del análisis en dientes y cálculo dental para investigar la dieta y prácticas de alimentación de los camélidos en Quilcapampa La Antigua (835-900 dC). Los datos taxonómicas específicos de los alimentos consumidos, sumado a los datis botánicos del cálculo dental complementan las impresiones más generales de las vías fotosintéticas obtenidas mediante el análisis isotópico. Los resultados sugieren que la dieta de los camélidos incorporó maíz (Zea mays), algarrobo (Prosopis sp.), papa chuño (Solanum sp.) y otros recursos. El perfil de la historia de vida de un camélido (Individuo 3) revela cambios en la dieta, principalmente desde plantas C3 a mayor consumo de plantas C4 a medida que el animal envejecía. Este patrón está respaldado por los resultados de isótopos de carbono que indican que este individuo pasó su juventud en la ecozona del valle medio, antes que su vida se tornara más móvil. Este ejemplo de historia de vida muestra que los análisis isotópicos y microbotánicos son enfoques complementarios y revelan un patrón de trashumancia estacional que unió la vida de humanos y animales a través de las redes de caravanas que atravesaban los Andes centrales durante el Horizonte Medio (600-1000 dC).

Type
Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of the Society for American Archaeology

Camelid management was a cornerstone of interregional interaction and societal sustainability in the ancient central Andes. Small-scale agropastoral practices—the cultivation of crops and management of livestock—predominated in pre-Wari eras, during which locally oriented animal husbandry often limited intergroup exchange and long-distance trade (Bonavia Reference Bonavia1996). Widening interactions associated with the emergence of the Wari Empire in the Middle Horizon (AD 600–1000) brought about significant changes in the relationships between humans and camelids. This article explores some of these seasonal pastoral management decisions in southern Peru using an innovative combination of stable isotope analysis of dentition and microbotanical analysis of dental calculus (see also Cagnato et al. Reference Cagnato, Nicolas Goepfert, Gabriel Prieto and Dufour2021). When contextualized within a broader set of zooarchaeological and paleoethnobotanical data, complementary analyses of stable isotope and microbotanical data provide a more robust picture of camelid diets and management practices.

Carbon (δ13C) and nitrogen (δ15N) stable isotope studies have shaped our knowledge of the timing and amount of C4 plant consumption, as well as the use of fertilizer in agriculture (e.g., Bogaard et al. Reference Bogaard, Heaton, Poulton and Merbach2007; Santana-Sagredo et al. Reference Santana-Sagredo, Schutling, Méndez-Quiros, Vidal-Elgueta, Uribe, Loyola and Maturana-Fernández2021; Szpak et al. Reference Szpak, Millaire, White and Longstaffe2012). Isotopic analyses of stable oxygen (δ18O) and radiogenic strontium (87Sr/86Sr) have shed light on migration and pastoral transhumance practices (e.g., Hakenbeck et al. Reference Hakenbeck, Jane Evans and Fóthi2017; Knudson Reference Knudson2009; Knudson et al. Reference Knudson, Emily Webb and Longstaffe2014). However, isotopic approaches without context are limited by a lack of dietary resolution. For example, δ13C values can speak to the relative amount of C3 and C4 plant consumption but cannot identify the genus/species of the plant(s) consumed (DeNiro and Epstein Reference DeNiro and Epstein1978; van der Merwe Reference van der and Nikolaas1982).

Microbotanical analysis offers promise in addressing the limitations of isotopic analysis. Seminal starch granule and phytolith studies of South American contexts (e.g., Dickau et al. Reference Dickau, Bruno, Iriarte, Prümers, Betancourt, Holst and Mayle2012; Duncan et al. Reference Duncan, Pearsall and Benfer2009; Pagán-Jiménez et al. Reference Pagán-Jiménez, Guachamín-Tello, Romero-Bastidas and Constantine-Castro2016; Zarrillo et al. Reference Zarrillo, Pearsall, Scott Raymond, Tisdale and Quon2008) demonstrate that microbotanical techniques complement macrobotanical analysis by producing direct evidence of food consumption from analyzing residues such as dental calculus. Dental calculus is a mineralized plaque biofilm that forms through the calcification of plaque deposits on the surface of teeth (Hillson Reference Hillson2005; Wright et al. Reference Wright, Dobney and Weyrich2021). Calculus deposits are located near salivary glands, where saliva provides the mineral components of calculus (Hillson Reference Hillson2005:289) and the enzymes (α–amylase) that break down carbohydrates (e.g., starch; Scannapieco Reference Scannapieco, Torres and Levine1993).

Calculus is common in domestic animals because their softer diets require less mastication, but wild animals can also produce thin, darkly stained patches that are presumably calculus (Hillson Reference Hillson2005:289–290). Microbotanical analysis of dental calculus is a burgeoning area of research into archaeological evidence of human plant consumption (Hart Reference Hart2014; Henry and Piperno Reference Henry and Piperno2008; Liu et al. Reference Liu, Duncan, Chen, Liu and Zhao2015; Madella et al. Reference Madella, García-Granero, Out, Ryan and Usai2014; Mickleburgh and Pagán-Jiménez Reference Mickleburgh and Pagán-Jiménez2012; Piperno and Dillehay Reference Piperno and Dillehay2008). Yet the use of dental calculus to elucidate animal subsistence strategies has been underexplored (but see Asevedo et al. Reference Asevedo, Winck, Mothé and Avilla2012; Middleton and Rovner Reference Middleton and Rovner1994; Weber and Price Reference Weber and Price2016)—particularly in herbivores—and rarely paired with stable isotope results (cf. Asevedo et al. Reference Asevedo, Winck, Mothé and Avilla2012).

This article combines microbotanical analysis of dental calculus (n = 9) and isotopic analysis (n = 10) to study camelids from the site of Quilcapampa (AD 835–900) in the Sihuas Valley of Peru. This dual approach is particularly useful for studying periods with limited architectural evidence of camelid management, such as the Middle Horizon. Our synthesis of both datasets reveals that distinct life-history stages were marked by shifts in camelid dietary composition and mobility strategies.

Background

Agropastoralism remains an important part of the political economy throughout much of the Andes (Bonavia Reference Bonavia1996; Capriles Reference Capriles2014; deFrance Reference deFrance, Capriles and Tripcevich2016; Moore Reference Moore, Capriles and Tripcevich2016; Szpak et al. Reference Szpak, Millaire, White and Longstaffe2014, Reference Szpak, Millaire, White, Lau, Surrette and Longstaffe2015; Takigami et al. Reference Takigami, Uzawa, Seki, Morales Chocano and Yoneda2020; Wheeler et al. Reference Wheeler, Russel and Redden1995). Of the four camelid species native to the region, two are wild—vicuñas (Lama vicugna) and guanacos (Lama guanicoe)—and two are domesticated: llamas (Lama glama) and alpacas (Vicugna pacos). Andean people commonly use camelids for food, as pack animals, and for economic products such as fibers that can be woven into textiles. Domesticated camelids require grazing, and family units often manage herds by foddering with agricultural fields on a rotational basis (Bonavia Reference Bonavia1996; Browman Reference Browman1974:191, Reference Browman, Salzman and Galaty1990; Caro Reference Caro1985; Dantas et al. Reference Dantas, Figueroa and Laguens2014; Flores Ochoa Reference Flores Ochoa1968; Kuznar Reference Kuznar, Capriles and Tripcevich2016).

Domesticated camelids can travel long distances, with the llama serving as a pack animal. Central Andean verticality contributes to notable variation in plant growing conditions and native fauna. Lower plateaus, such as the yungas (2,300–500 m asl), offer arid to temperate growing conditions, whereas only frost-resistant crops can grow on the snowy higher plateaus (e.g., puna: 4,800–3,500 m asl; Gomez Molina and Little Reference Gomez Molina and Little1981; Vining Reference Vining, Capriles and Tripcevich2016). Yet the yungas experiences greater seasonal variation in wild vegetation than the highlands. Camelid caravans can connect resource zones into “vertical archipelagos” (Murra Reference Murra and Diamond1960; Vining Reference Vining, Capriles and Tripcevich2016; Vining and Williams Reference Vining and Williams2020). They can also connect coastal river valleys along “horizontal archipelagos” (Shimada and Shimada Reference Shimada and Shimada1985).

Foods eaten by domesticated camelids vary because camelids can stay local or travel across ecozones. Maize is commonly incorporated into direct camelid foddering and grazing strategies today (Popenoe et al. Reference Popenoe, King, Leon and Kalinowski1989). However, Cadwallader and colleagues (Reference Cadwallader, Beresford-Jones, Whaley and O'Connell2012) argue that maize, a C4 crop, may only represent one-third of the Andean dietary carbon isotope signal in the archaeological record based on their study of δ13C values of nearly 90 wild plants from the Peruvian south coast. A mixed diet makes sense ethnographically because amaranth (Amaranthus caudatus) or kiwicha, also a C4 crop, and field stubble are commonly grazed (Brack Egg Reference Brack Egg1999; Candia and Dealmasso Reference Candia and Dealmasso1995; Gross et al. Reference Gross, Koch, Malaga, de Miranda, Schoeneberger and Trugo1989). Saltgrass (Distichlis spicata), matted grama (Bouteloua simplexi), and muhly (Muhlenbergia sp.) are other C4 wild coastal plant taxa available to herds (Candia and Dealmasso Reference Candia and Dealmasso1995; Dufour et al. Reference Dufour, Goepfert, León, Chauchat, Jordán and Sánchez2014; Panarello and Fernández Reference Panarello and Fernández2002; Shimada and Shimada Reference Shimada and Shimada1985; Thornton et al. Reference Thornton, deFrance, Krigbaum and Williams2011; Vining Reference Vining, Capriles and Tripcevich2016). Important C3 plant contributions to the contemporary herd diet include (1) cultivated potato (Solanum spp.) and quinoa (Chenopodium quinoa), (2) fruits of algarrobo trees (Prosopis spp.), and (3) wild grasses such as ichu (Stipa ichu) found in the altiplano at 3,500 m asl (Cadwallader et al. Reference Cadwallader, Beresford-Jones, Whaley and O'Connell2012; Samec et al. Reference Samec, Yacobaccio and Panarello2017; Vining Reference Vining, Capriles and Tripcevich2016).

Decreasing human mobility and the increased corralling of newborn animals and large camelids suggest that camelid herding and management practices appear by about 4600–3000 BP (Mengoni Goñalons and Yacobaccio Reference Mengoni Goñalons, Yacobaccio, Zeder, Bradley, Emshwiller and Smith2006). Izeta and colleagues’ (Reference Izeta, Laguens, Marconetto and Scattolin2009) study of δ13C values in southern Argentinian camelids reveals higher δ13C values over time, suggesting the increased consumption of C4 plants. In conjunction with cultivated terraces and corrals, the evidence suggests people began feeding agricultural refuse to camelids during the first millennium AD (211).

Dietary isotope signals can be complicated by transhumance. Andean foddering practices are particularly difficult to interpret because of interactions across the “vertical archipelago” (Knudson Reference Knudson2009; Knudson et al. Reference Knudson, Emily Webb and Longstaffe2014; Scaffidi and Knudson Reference Scaffidi and Knudson2020). Herd management practices and foddering sources can be especially hard to disentangle during periods of heightened long-distance interaction like the Middle Horizon (AD 600–1000; Isbell Reference Isbell, Manzanilla and Chapdelaine2009). Stable oxygen (δ18O) and radiogenic strontium (87Sr/86Sr) isotopes can aid in differentiating between foddering and seasonal migrations by adding detail regarding altitudinal history (Hakenbeck et al. Reference Hakenbeck, Jane Evans and Fóthi2017; Thornton et al. Reference Thornton, deFrance, Krigbaum and Williams2011).

The difficulties of understanding Middle Horizon agropastoralism are exemplified in Quilcapampa, a Wari settlement in the yungas zone where communities could access both coastal and highland resources. Understanding which resource zones were used by Wari people can contribute to our broader understanding of Andean trade, mobility, and identity practices during this period. To reconstruct animal management strategies at the site, we summarize extant knowledge of the local environment and agropastoral practices before interpreting the results of isotope and microbotanical analyses of camelid teeth.

The Yungas, Quilcapampa, and Camelid Foddering

Quilcapampa was a 2 ha Wari outpost located about 80 km from the Pacific Ocean near the northern edge of southern Peru's Pacific Piedmont, where the coastal plain meets the Andean foothills (Figures 1 and 2; Supplemental Text 1; Jennings et al. Reference Jennings, Berquist, Spence-Morrow, Bikoulis, Gonzales-Macqueen, Yépez Álvarez, Bautista, Jennings and Swenson2018, Reference Jennings, Rizzuto, Yépez Álvarez, Jennings, Yépez Álvarez and Bautista2021). Llama (L. glama) and alpaca-sized (V. pacos) individuals were present at the site, with osteological analysis suggesting that the animals were used for meat, transport, and fiber (Alaica et al. Reference Alaica, Cuzcano, La Rosa, Jennings, Yépez Álvarez and Bautista2021). At 800 m asl, Quilcapampa was situated in the mid-altitude yungas zone (2,300–500 m asl). With only 50–200 mm of rainfall each year, the hyperarid region offered limited camelid fodder. Cacti (Haageocereus sp., Neoraimondia sp., Opuntia sp.) were present on the valley slopes and quebradas, although river sedges (Cyperaceae), algarrobo (Prosopis spp.), and grasses/shrubs (e.g., Atriplex sp., Baccharis sp., Bidens sp., Eragrostis sp.) were restricted to the river bottoms (Biwer Reference Biwer2019; Moneresinos-Tubée and Mondragón Reference Moneresinos-Tubée and Mondragón2014). Cultivated fodder included maize, pacay (Inga feuillei), and lúcuma (Pouteria lucuma). Quinoa and potato, both highland-associated foods, were also available for consumption at Quilcapampa (Supplemental Table 1).

Figure 1. (a) Location of Quilcapampa and other sites mentioned in the text (Landsat imagery courtesy of NASA Goddard Space Flight Center and US Geological Survey); (b) plan of Quilcapampa showing the raised plaza, core compounds immediately to the west, and a surrounding outlying area. (Color online)

Figure 2. Aerial view of Quilcapampa showing the contrast between fertile river bottoms and arid upland areas. Photograph courtesy of Stephen Berquist. (Color online)

Isotopic and Dental Calculus Analysis

To better understand camelid foddering strategies at Quilcapampa, our study combines stable isotope analysis of camelid teeth with microbotanical analysis of starch granules/phytoliths from the corresponding dental calculus. We selected 10 teeth (NISP = 10) representing four individuals (MNI = 4) identified through macroscopic observation of diagnostic features (Gifford-Gonzalez Reference Gifford-Gonzalez2018; Pacheco Torres et al. Reference Pacheco Torres, Altamirano Enciso and Guerra Porras1979; Reitz and Wing Reference Reitz and Wing2008; Wheeler Reference Wheeler1982). Dental eruption and occlusal wear indicate that these individuals range from nine months to three years in age (Figure 3; De Nigris Reference De Nigris2004; Hillson Reference Hillson2005; Wheeler Reference Wheeler1982). Calculus was recovered from nine of the 10 teeth. After we collected the calculus, these teeth were analyzed for stable and radiogenic isotopes.

Figure 3. Camelid dentition and wear patterns: (a) Individual 1; (b) Individual 2; (c) Individual 3; and (d) Individual 4. (Color online)

Stable and Radiogenic Isotope Analyses

Stable and radiogenic isotope analyses can be conducted on animal bone, enamel, dentin, and fiber. These tissues have different rates of formation and remodeling. Cranial and postcranial bone, for example, remodels every few years, whereas dental enamel is formed in utero or during the first years of life and does not remodel (Wheeler Reference Wheeler1982). Two types of tissues were subject to analysis: dentine collagen (δ13C and δ15N stable isotopes) and enamel carbonate (δ13C, δ18O, and 87Sr/86Sr isotopes).

The arid, warmer environment of the coast is ideal for C4 vegetation, enriching δ13C values of foddered and grazing herds. Because wild grasses (C3 plants) are commonly used as livestock fodder in the highlands (Samec et al. Reference Samec, Yacobaccio and Panarello2017), carbon isotopic compositions tend to be lower than at the coast (Bryant and Farfan Reference Bryant and Farfan1984; Reiner and Bryant Reference Reiner and Bryant1986; Szpak et al. Reference Szpak, White, Longstaffe, Millaire and Vásquez Sánchez2013; Vining Reference Vining, Capriles and Tripcevich2016). Estimating the contribution of C3 and C4 to diet in collagen samples is possible by using the estimated mean preindustrial δ13C values of pure-C3 and pure-C4 feeders (Dufour et al. Reference Dufour, Goepfert, León, Chauchat, Jordán and Sánchez2014:Figure 5).

δ15N isotopic compositions of vegetation vary based on aridity, input from marine ecosystems, and the fertilization of agricultural fields using bird guano (DeNiro and Epstein Reference DeNiro and Epstein1981; Santana-Sagredo et al. Reference Santana-Sagredo, Schutling, Méndez-Quiros, Vidal-Elgueta, Uribe, Loyola and Maturana-Fernández2021; Szpak et al. Reference Szpak, Millaire, White and Longstaffe2012). On the coast, herds have access to wild vegetation from arid contexts and seaweed (or yuyo). Greater quantities of these sources contribute to increasing δ15N, which reaches values as high as 10.0‰.

Elevation, season, humidity, and temperature affect δ18O from water sources. Lower δ18O values are more common in high-altitude locations (La Paz Bolivia: –13.3‰ to –10.8‰) than on the coast (or chala, 500–1 m asl) or the mid-valley (or yungas, 2,300-500 m asl: –3.3‰ to –5.7‰; Knudson Reference Knudson2009). Positive δ18O values are related to consuming water from evaporated sources, which was recorded in camelids from the central coast (Tomczyk et al. Reference Tomczyk, Milosz Giersz, Kamenov and Krigbaum2019).

Radiogenic strontium (87Sr/86Sr) values vary broadly by lithology and crustal age, which correlate with elevation in the Andes; the coast has lower ratios (0.705–0.708) than the highlands (0.707–0.711; Knudson et al. Reference Knudson, Emily Webb and Longstaffe2014; Thornton et al. Reference Thornton, deFrance, Krigbaum and Williams2011; Scaffidi and Knudson Reference Scaffidi and Knudson2020). In Arequipa, strontium baseline analysis conducted on local plants (n = 8) revealed a range of 87Sr/86Sr = 0.70797 ± 0.00115 (1σ; Knudson et al. Reference Knudson, Emily Webb and Longstaffe2014). To establish the local strontium baseline for Quilcapampa, we use two standard deviations (2σ) in values, resulting in a reference range from 0.70567 to 0.71027.

Stable and radiogenic isotope analysis of 10 dental specimens from Quilcapampa was conducted in the Archaeological Chemistry Laboratory (ACL) and Metals, Environmental and Terrestrial Analytical Laboratory (METAL) at Arizona State University (ASU). In the ACL, samples were photographed and mechanically cleaned with a Dremel Minimite-750 cordless drill equipped with a rotary burr. This process removed adhering organic matter or contaminants and the outermost layer of enamel most susceptible to diagenetic contamination (Budd et al. Reference Budd, Montgomery, Evans and Barreiro2000; Montgomery et al. Reference Montgomery, Budd and Evans2000; Waldron Reference Waldron1981, Reference Waldron1983; Waldron et al. Reference Waldron, Khera, Walker, Wibberley and Green1979). The outer surfaces of the roots were also abraded to remove cementum. Each tooth was sampled for both dentine and enamel. Enamel powder was sampled using a Dremel burr first along the column of the tooth crown; then the dentine was sampled with a Dremel saw to extract a thin slice running the length of the crown to the root. Sample preparation methods for dental collagen, hydroxyapatite carbonate, and enamel samples are described in Supplemental Text 2.

Starch and Phytolith Analysis

Formation Processes and Micro-Taphonomy. Starch and phytolith recovery from dental calculus are limited by diagenetic factors related to formation processes and micro-taphonomy. The frequency of starch granules found archaeologically is greatly reduced by the immediate breakdown of starch and conversion to sugars by salivary α–amylase, an essential part of the dental calculus formation process (Scannapieco et al. Reference Scannapieco, Torres and Levine1993). The chemical breakdown of starch by saliva during the approximately 15 s that camelids retain their cud (Fowler Reference Fowler2010) may also be exacerbated by any preexisting damage to the starch caused by food preparation or cooking techniques; chuño blanco starches, for example, would be more susceptible to destruction than unaltered potato starch because they are typically swollen beyond normal dimensions, resulting in damage to their margins and internal morphology (Melton et al. Reference Melton, Biwer and Panjarjian2020). The physical breakdown of starches can also be induced by mastication, which is repeated by camelids about 25–35 times per bolus (Fowler Reference Fowler2010). Starchy diets may create more opportunities for deposition in calculus and survival to archaeological identification; however, counts of recovered starches cannot be directly related to exploitation intensity (Leonard et al. Reference Leonard, Vashro, O'Connell and Henry2015). Phytoliths are typically present in nonedible plant parts (e.g., maize cobs, husks), but because these parts are not chewed or consumed by all animals, there is a bias against the recovery of phytoliths as opposed to starch. Thus, archaeological calculus typically reveals small numbers of starches and phytoliths, identifying specific foods consumed while not excluding unidentified taxa from dietary reconstructions.

Laboratory Procedures. Camelid dental calculus samples from Quilcapampa were collected using sterile dental picks cleaned with methanol. Starch granules and phytoliths were extracted from nine samples of calculus in the Integrative Subsistence Laboratory at the University of California, Santa Barbara (UCSB-ISL). Modern contamination was controlled through standard approaches (Crowther et al. Reference Crowther, Michael Haslam, Walde and Mercader2014; Henry and Piperno Reference Henry and Piperno2008). Each tube was subject to extraction and slide mounting according to UCSB–ISL standard laboratory procedures (Supplemental Text 3) based on published protocols on the isolation of microbotanical remains from dental calculus (Henry and Piperno Reference Henry and Piperno2008; Mickleburgh and Pagán-Jiménez Reference Mickleburgh and Pagán-Jiménez2012).

Initially, it was unclear whether macrobotanical desiccated potatoes found at the site could be identified as chuño. To assess whether these potatoes could be a possible source for any chuño starch granules found in camelid dental calculus, we selected for microbotanical analysis one desiccated potato (Solanum tuberosum), with a brown appearance and a white interior, from the macrobotanical assemblage. Supplemental Text 4 discusses procedures for starch collection from the desiccated potato.

We used a Brunel SP-400 Metallurgical Microscope (×50–×600), equipped with transmitted/incident illumination systems and polarization filters, in microbotanical identification. Slides were scanned for starch granules under transmitted nonpolarized/polarized light at 100× magnification, followed by removal of the polarization filter and a separate scan for phytoliths at 200× magnification. All microbotanicals were photographed at 400× under nonpolarized transmitted light, with starch granules also photographed under polarized light to record the presence/appearance of extinction crosses (typically visible in undamaged and mildly damaged starch granules) and the degree of birefringence (which can be decreased or nonexistent due to damage).

Starch granules and phytoliths were identified with reference to micrographs of modern plants native to the study region (Capparelli et al. Reference Capparelli, Pochettino, Lema, López, Andreoni, Ciampagna and Llano2015; Giovanetti et al. Reference Giovanetti, Lema, Bartoli and Capparelli2008; Musaubach and Berón Reference Musaubach and Berón2017; Pagán-Jiménez Reference Pagán-Jiménez2015) and the UCSB–ISL paleoethnobotanical comparative collection. Interpretations of damage patterns were based on the results of modern experimental studies (Babot Reference Babot, Hart and Wallis2003; Henry et al. Reference Henry, Hudson and Piperno2009) and recent research on the impacts of chuño production practices on starch morphology and metrics (Melton et al. Reference Melton, Biwer and Panjarjian2020). Taxonomic identification was not always possible: some plant specimens were too severely damaged or lacked diagnostic features altogether. As a result, these specimens were classified as “unidentified.”

Results

Stable Isotope Analyses

Stable and radiogenic isotope analyses of 10 dental specimens from Quilcapampa were successful for all samples, except the dentine collagen from ACL-10424 (Individual 1); the carbon to nitrogen ratio of this dentine sample was outside the range for acceptable preservation (2.9–3.6; DeNiro and Epstein Reference DeNiro and Epstein1978, Reference DeNiro and Epstein1981; Figures 3–6; Table 1). Each dental specimen was sampled along the tooth column. Isotopic compositions for each tissue relate to four individual animals.

Figure 4. Scatterplot of stable carbon and oxygen isotopes from enamel carbonate for Individuals 1–4.

Figure 5. Bar graph indicating variation of strontium values: Individual 1 (blue, solid), Individual 2 (orange, horizontal lines), Individual 3 (gray, left-diagonal lines), and Individual 4 (purple, right-diagonal lines), with the local baseline range demarcated. (Color online)

Figure 6. (a) Scatterplot of stable carbon and nitrogen isotopes from dentin collagen for Individuals 2–4; higher carbon isotopes are related to greater contributions from C4 plants; (b) scatterplot of stable oxygen and radiogenic strontium isotopes from enamel for Individuals 1–4.

Table 1. Stable and Radiogenic Isotope Values for Individuals 1–4.

Individual 1 is represented by a first molar (M1; ACL-10424) yielding δ13Ccarb = –12.0‰, δ18OVPDP = –4.3‰, and 87Sr/86Sr = 0.70609 (Figures 4 and 5). The isotopic composition indicates that this individual had a diet of <20% C4 plants (Figure 6a; Dufour et al. Reference Dufour, Goepfert, León, Chauchat, Jordán and Sánchez2014). This animal consumed high amounts of C3 plants and resided in the yungas and lower quechua ecozones (2,300-500 m asl; Knudson Reference Knudson2009). This association suggests that its mother made frequent sojourns to higher-altitude regions during the formation of its first molar.

Individual 2 is represented by a deciduous fourth premolar (dP4) and M1 yielding average δ13Ccoll = –17.2‰, δ15Ncoll = 9.55, δ13Ccarb = –10.5‰, δ18OVPDP = 2.1‰, and 87Sr/86Sr = 0.708925 (Figure 6a–b). The collagen and carbonate isotope signatures indicate that this individual had a diet of ~30% C4 plants (Figures 5 and 6; Dufour et al. Reference Dufour, Goepfert, León, Chauchat, Jordán and Sánchez2014). Individual 4 is represented by a second molar (M2) yielding δ13Ccoll = –18.4‰, δ15Ncoll. = 7.5, δ13Ccarb = –9.3‰, δ18OVPDP = 1.8‰, and 87Sr/86Sr = 0.70775. The collagen and carbonate isotopic composition indicates that this individual had a diet of 20%–40% C4 plants. The isotopic compositions of teeth from Individuals 2 and 4 indicate a higher contribution of C4 plants than for Individual 1, which suggests access to greater crop diversity and even mobility between the coast and highlands.

Individual 3 is represented by a deciduous third premolar (dP3), dP4, permanent P4, M1, M2, and third molar (M3) yielding average δ13Ccoll = –18.1‰, δ15Ncoll = 7.3, δ13Ccarb = –9.5‰, δ18OVPDP = –2.8‰, and 87Sr/86Sr = 0.70729. The collagen and carbonate results indicate that this individual had a diet of 20%–30% C4 plants. The average isotopic compositions for early-forming teeth (dP3, dP4, M1, and M2) differ from late-forming teeth (P4 and M3). Comparing the contribution of different foddering sources, early-forming teeth reflect a diet of 20%–30% C4 plants, whereas late-forming teeth reflect a diet of 30%–40% C4 plants. Earlier in this animal's life it consumed more C3 plants, indicated by lower carbon isotopic composition and water sources with lower oxygen isotopic composition. Individual 3's diet changed through time, with a higher contribution of C4 plants later in life.

The 10 dental specimens analyzed for stable and radiogenic isotopes indicate mixed C3 and C4 plant consumption and mobility between the coast and highlands. Isotope analyses of teeth formed in utero are important for understanding the mobility of pregnant female animals. Life-history findings from our multitooth analysis are elaborated by the results of our microbotanical analysis of dental calculus.

Microbotanical Analysis of Camelid Dental Calculus

Four starch granules and one phytolith were recovered from calculus on camelid teeth from three individuals (Table 2). Individual 1 is represented by one sample (ACL-10424) yielding a starch granule consistent with maize (Figure 7a–b) in terms both of its size and morphological presentation. This angular and irregular granule has an extinction cross obscured in the lower-left corner of the starch in Figure 7b, likely due to damage. The cause of this damage is unclear because of its mild presentation.

Figure 7. Starches and phytolith recovered from dental calculus of Individuals 1–3: (a) maize-like starch granule, ACL-10424, nonpolarized light; (b) maize-like starch granule, ACL-10424, polarized light; (c) potato starch granule, ACL-10500, nonpolarized light; (d) potato starch granule, ACL-10500, polarized light; (e) potato starch granule, ACL-10501, nonpolarized light; (f) potato starch granule, ACL-10501, polarized light; (g) algarrobo starch granule, ACL-10501, nonpolarized light; (h) algarrobo starch granule, ACL-10501, polarized light; and (i) unidentified phytolith, ACL-10498, nonpolarized light. Scale bar in each micrograph is 20 μm in length.

Table 2. Morphological Attributes of Starch Granules and Phytoliths in Dental Calculus of Quilcapampa Camelids.

Individual 2 is represented by one sample (ACL-10498) yielding an unidentified phytolith (see Figure 7i). This phytolith does not clearly match any taxonomically diagnostic criteria and thus remains unidentified. Unfortunately, except for the phytolith finding that broadly suggests dental contact with some form of hardy plant remains (e.g., leaf, stalk, or cob), microbotanical results do not provide any additional insights into the diet of this individual.

Individual 3 is represented by two samples (ACL-10500, 10501) yielding one algarrobo granule and two potato starch granules (see Figure 7c–h). Algarrobo fruits are a foraging source today for both humans and camelids, particularly in the yungas where the trees are abundant (Román Godines Reference Román Godines2013; Rostworowski Reference Rostworowski de Diez Canseco1981:61). The connection between algarrobo and camelids also extends into the past: dung from the site of Cerro Sapamé (Late Intermediate to Late Horizon period) provides direct evidence of algarrobo as fodder (Shimada and Shimada Reference Shimada and Shimada1985). Although algarrobo seeds are absent from Quilcapampa's macrobotanical assemblage (Biwer and Melton Reference Biwer, Melton, Jennings, Yépez Álvarez and Bautista2021), starches have been recovered from artifacts associated with feasting at other sites (e.g., Buena Vista; see Duncan et al. Reference Duncan, Pearsall and Benfer2009). Thus, we cannot rule out the possibility that algarrobo fruits may have been obtained by camelids through provisioning and trash raiding, in addition to free grazing.

The potato granule found in the ACL-10500 sample has a size, shape, and hilum location that fit expectations for chuño, but its internal structure is clearly damaged as signified by its faded appearance (see Figure 7c–d). Its extinction cross is obscured on the left side due to damage. This starch fit expectations for chuño negro based on the softened appearance of its border, bubbled internal presentation, and appropriate length-to-width ratio (Melton et al. Reference Melton, Biwer and Panjarjian2020). ACL-10501 also yielded one potato starch granule. Damage is indicated by missing areas along the upper portion of the border (see Figure 7e) that obscure the upper-right quadrant of the extinction cross (see Figure 7f). Based on the broken nature of the border, the damage was likely caused by grinding activities. Grinding damage is expected for dental calculus, particularly from camelids, because of the mastication involved in food consumption. There is also a possibility the granule was exposed to boiling or baking based on its uneven internal texture (Henry et al. Reference Henry, Hudson and Piperno2009), which could have occurred before consumption. To gain more guidance on the human use of chuño at Quilcapampa, we looked to starches from the desiccated potato sampled for starch analysis.

Starch granules from the archaeological potato (Figure 8) are generally irregularly ovate in shape, with some projections that result in a triangular or trapezoidal appearance (see Figure 8a). Transverse and longitudinal fissures are common, with hila openings devoid of fissures being abundant but less common. Cracks occur around the perimeters of some starches (see Figure 8e) representing damage and are seen most frequently in starches exposed to physical damage (Henry et al. Reference Henry, Hudson and Piperno2009); for micrographs of unaltered starches from modern Andean potato varieties, see Cruz and coworkers (Reference Cruz, Pablo Ribotta and Iturriaga2016) and Rumold (Reference Rumold2010). In her study of modern chuño starches, Babot (Reference Babot, Hart and Wallis2003) found granules with fragmentation around the perimeter and in other locations. Physical damage to chuño starches is most likely the result of trampling that is part of both chuño negro and chuño blanco production processes. Several granules exhibited a faded, more transparent appearance that is characteristic of chuño starches; the borders of these starches are faint, and they demonstrate occasional vacuoles and missing areas under polarized light (see Figure 8b). Extinction crosses are visible in most but not all starches because starches with a faded appearance do not exhibit birefringence: this is a diagnostic characteristic of these starches. Extinction cross arms are bent or widened in some starches, particularly near the hilum (see Figure 8d). One arm per starch is occasionally bent (a defining characteristic of chuño negro starches; see Melton et al. Reference Melton, Biwer and Panjarjian2020); however, the bend angle is not always like that observed in modern chuño negro examples. Our observations of this specimen help support the availability of chuño to camelids in a yungas context while also providing a morphological record that can be compared with archaeological starches from other sites.

Figure 8. Starch granules in desiccated potato from the Quilcapampa macrobotanical assemblage: (a, c) nonpolarized lighting at 200× magnification; (b, d) polarized lighting at 200× magnification; (e) nonpolarized lighting at 400× magnification. Scale bar in each micrograph is 20 μm in length. Arrows indicate features referenced in text.

Discussion

The abundance of macrobotanical potato (likely chuño negro) and maize remains at Quilcapampa supports our suggestion that chuño and maize were consumed by camelids living at this site. The absence of algarrobo in the macrobotanical record associated with anthropogenic refuse deposits suggests that it may have been largely used as camelid fodder. Because algarrobo trees are located closer to the Sihuas River, the introduction of algarrobo pods into camelid diets may have occurred during periodic grazing along the river's edge. Moreover, morphological characteristics of the desiccated potato recovered at Quilcapampa are consistent with expectations for chuño, which was also identified in microbotanical residues on ceramic and groundstone artifacts at the site (Biwer and Melton Reference Biwer, Melton, Jennings, Yépez Álvarez and Bautista2021, Reference Biwer and Melton2022). Situating our microbotanical results alongside the site's stable and radiogenic isotope findings, other botanical and faunal datasets, and environmental conditions allows us to consider how camelids may have gained access to the identified resources.

During the Middle Horizon, camelids around Quilcapampa had few grazing opportunities because of the high aridity and limited availability of weedy plants during dry seasons. Although llamas and alpacas in the highlands could graze on various wild grasses, camelids living in the yungas of Peru's southern coast likely relied almost exclusively on what grew in the heavily cultivated river valley bottoms. To sustain their animals, herders depended in part on staple foods and evaporated water sources for hydration. Stable isotope analysis demonstrates variation among the diets of different camelids at Quilcapampa, with some individuals having a greater contribution of C4 plants than others. All radiogenic strontium isotopic compositions are within the local range (see Figure 5; Knudson et al. Reference Knudson, Emily Webb and Longstaffe2014), but Individual 3 displays an important difference between its early- and late-forming teeth. The early-forming teeth have characteristic signatures for the yungas ecozone, whereas the later-forming teeth have a higher strontium isotopic composition. Oxygen signatures support this pattern: the early-forming teeth fall within the yungas ecozone, and late-forming teeth have isotopic compositions that indicate the consumption of water from evaporated sources. This finding aligns with the greater mobility that older camelids typically experience when they join caravan herds. Thus, our results from Individual 3 highlight a possible life history of early rearing in more coastal or yungas environments and later life sojourns to the highlands and coast (a seasonal rotation of foddering camelids on maize stubble was noted by Dantas and colleagues [Reference Dantas, Figueroa and Laguens2014]).

Our understanding of local management strategies is deepened by pairing isotopic and botanical data. Although no starch granules/phytoliths from wild grasses were identified, ichu thatch and seeds were found in a few excavation units, suggesting that seasonal grasses and sedges could have been provisioned as C3 fodder from the valley bottom or highland sources (Bruno and Hastorf Reference Bruno, Hastorf, Capriles and Tripcevich2016). Microbotanical analysis provides direct evidence for algarrobo fruits as a C3 source, either provisioned by humans or consumed during visits to the evaporated water sources that these trees tend to inhabit in otherwise arid landscapes (Beresford-Jones et al. Reference Beresford-Jones, Arce T., Whaley and Chepstow-Lusty2009).

Human-processed C3 cultigens were also incorporated into camelid diets. Microbotanical results from dental calculus revealed starch granules of potato, likely chuño negro. Chuño was an imported resource at Quilcapampa, indicating connections to the highlands and perhaps the Wari heartland. Lightweight, edible for years, and nutrient-rich, chuño could have been directly given to herds as fodder, consumed by camelids rummaging through middens, or both. Desiccated chuño potatoes are prevalent in the core area of Quilcapampa, indicating that they likely served as an everyday staple.

Microbotanical analyses also supplement stable isotope findings by indicating that maize contributed to C4 plant inputs. Maize was widely processed at Quilcapampa and was thus available to camelids in many ways. Our findings align well with the isotopic evidence for maize foddering at Conchopata, a contemporaneous Wari site in the Ayacucho Basin. Finucane and colleagues (Reference Finucane, Agurto and Isbell2006) found higher carbon isotopic compositions among Conchopata's camelids, which suggests the active pasturing of herds on maize fields. A similar scenario could have unfolded in Quilcapampa, where the yungas zone provided fertile lands for maize agriculture, although direct foddering and camelid rummaging in middens represent additional possibilities.

Quilcapampa's location is ideal for maize agriculture, and the maize consumed by the camelids was likely grown nearby. However, dental calculus represents accumulated dietary behaviors (like stable isotopes), and the deposition of chuño, algarrobo, and maize-like starch could be from a single meal or from long-term habitual practices in a seasonal round. Isotope results suggest that Quilcapampa camelids varied in diet and grazing locales over the course of their lives. Individual 3, for example, was reared largely on C3 plants as a juvenile but had greater input (~30%–40%) from C4 sources later in life (see Figure 6a). Strontium isotope results demonstrate that this animal spent its early years in a lower radiogenic region compared to its later development. This shifting pattern suggests that Individual 3 spent its juvenescence grazing in fertile coastal pastures, followed by a switch to a more arid locale like Quilcapampa, where grasses were less available and agricultural C4 staples were necessary to supplement input from local grazing resources. The nitrogen isotopic composition of teeth supports this switch: higher isotopic composition among late-forming teeth indicates that Individual 3's later life may have been spent in arid environments. Additionally, chuño can only be produced at altitudes above about 3,800 m asl (de Haan et al. Reference de Haan, Burgos, Arcos, Canto, Scurrah, Salas and Bonierbale2010), thus serving as an indicator of relations with the highlands that were almost certainly supported by llama caravans.

Middle Horizon caravan trails bisect the northern edge of the Pacific Piedmont (Bikoulis et al. Reference Bikoulis, Gonzalez-Macqueen, Spence-Morrow, Bautista, Álvarez and Jennings2018). Quilcapampa, like other Pacific Piedmont sites of the era (Nigra et al. Reference Nigra, Rosas, Lozada and Barnard2017), was oriented around these trails: both petroglyph evidence and faunal remains at the site reveal the important role that camelids played in maintaining Wari contacts between the highlands, coast, and intervalley regions of the yungas (Alaica et al. Reference Alaica, Cuzcano, La Rosa, Jennings, Yépez Álvarez and Bautista2021; Berquist et al. Reference Berquist, Gonzalez-Macqueen, Jennings, Jennings, Yépez Álvarez and Bautista2021). Ceramic, lithic, botanical, and textile evidence suggest that Quilcapampa's residents maintained interregional interactions throughout the site's short occupation. It is important to juxtapose these long-distance connections with local animal management in the yungas. Camelids were central to Quilcapampa's socially charged feasting regime that tied the core area's residents to those living elsewhere in the valley (Alaica et al. Reference Alaica, Cuzcano, La Rosa, Jennings, Yépez Álvarez and Bautista2021). Balancing the use of camelids as a source of meat, transport, and fiber required careful decision-making. Herders needed to calibrate the male:female and adult:subadult ratios of their animals and provide them with adequate fodder and water, whether at home or on the move.

Conclusions

Integrating stable isotope data on camelid teeth with microbotanical data of dental calculus adds specificity to ancient camelid foddering techniques, providing greater resolution of the diets and subsistence sources of animals managed by humans. Stable and radiogenic isotope analyses across the life histories of four animals from Quilcapampa revealed both C3 and C4 plant input and vertical mobility but were limited in their ability to identify specific resources that contributed to isotopic signatures. Microbotanical analysis of dental calculus from these same camelids identified C3 (algarrobo and potato) and C4 (maize) resources and showed that potatoes were likely processed by humans into chuño (likely chuño negro) before consumption by camelids. No starch granules or phytoliths of wild grasses were found in the calculus, but their absence does not eliminate the possibility that these resources may have been used for grazing when available.

Situating these results in the context of Quilcapampa's environmental surroundings and excavated subsistence assemblage suggests that camelid foddering in the yungas largely took place within the narrow confines of an arid and heavily domesticated landscape. Camelids ate a combination of local fodder and cultivated staples obtained from nearby fields or long-distance exchange, all of which were either actively or unintentionally supplied to the animals. Limited grazing opportunities meant that feeding camelids at Quilcapampa, as at other yungas settlements, was fundamentally different from many highland or coastal locales where native grasses were more plentiful. Our research suggests that these yungas settlements would have served critical roles as vital caravan nodes where camelids were provisioned, ensuring their sustenance in traversing terrain with sparse natural fodder. Newcomers to a region, like those who founded Quilcapampa, therefore needed regular access to local fields, fertile algarrobo groves, and evaporated water sources but also used imported highland foods to help sustain their herds. Although much work remains in unraveling seasonal migration, trade, and inter/cross-regional interactions during the Middle Horizon, we hope that this case study encourages future research combining different methodological approaches to understand mobility more fully in the ancient Andes.

Acknowledgments

We thank the reviewers of this article for their supportive feedback and suggestions that strengthened our interpretations and discussion. Excavations at Quilcapampa were conducted under the auspices of the Peruvian Ministry of Culture (Permit #218–2016–GDPA/VMPCIC/M). Facilities that supported this research include the Integrative Subsistence Laboratory (University of California, Santa Barbara) and the Archaeological Chemistry and Metals, Environmental and Terrestrial Analytical Laboratories (Arizona State University). Natalya Zolotova, Alexandra Greenwald, and Beth Koontz Scaffidi provided guidance during isotope sample preparation. University of California, Santa Barbara, undergraduate interns Ana Perez, Nicole Ellis, Rita Panjarjian, and Delenn Ganyo assisted in dental calculus sample preparation. Ruth Dickau graciously reviewed microbotanical identifications. We are grateful to fellow members of the Quilcapampa team for their tireless efforts investigating this ever-interesting site.

Funding Statement

Funding was provided by the Social Sciences and Humanities Research Council of Canada (Grant #43150212), National Geographic Society (Grant #9730015), Royal Ontario Museum (Kircheis Family Grant, Louise Hawley Stone Charitable Trust Grant, and New World Archaeology Grant), Wenner-Gren Foundation (Grant #9225), National Science Foundation (Grant #1634065), and the University of Toronto Archaeology Centre.

Data Availability Statement

All microbotanical and stable isotope data are reported in the body, figures, tables, and supplemental files of this manuscript. Macrobotanical data are available through the Digital Archaeological Conservancy (tDAR), and remains are curated in the University of California, Santa Barbara Integrated Subsistence Laboratory. There are no remaining microbotanical or stable isotope samples in curation.

Competing Interests

The authors declare none.

Supplemental Material

For supplemental material accompanying this article, visit https://doi.org/10.1017/laq.2022.80.

Supplemental Table 1. Macrobotanical Remains Identified at Quilcapampa.

Supplemental Text 1. Extended Descriptions of the Quilcapampa Site Related to Faunal and Macrobotanical Findings.

Supplemental Text 2. Stable and Radiogenic Isotope Sample Preparation Procedures.

Supplemental Text 3. Microbotanical Sample Extraction and Slide Mounting Procedures.

Supplemental Text 4. Procedures for Sampling Desiccated Potato Remains for Starch Analysis.

References

References Cited

Alaica, Aleksa K., Cuzcano, Patricia Quiñonez, and La Rosa, Luis Manuel González. 2021. Vertebrate and Invertebrate Remains at Quilcapampa. In Quilcapampa: A Wari Enclave in Southern Peru, edited by Jennings, Justin, Yépez Álvarez, Willy J., and Bautista, Stefanie, pp. 350391. University Press of Florida, Gainesville.CrossRefGoogle Scholar
Asevedo, Lidiane, Winck, Gisele R., Mothé, Dimila, and Avilla, Leonardo S.. 2012. Ancient Diet of the Pleistocene Gomphothere Notiomastodon platensis (Mammalia, Proboscidea, Gomphotheriidae) from Lowland Mid-Latitudes of South America: Stereomicrowear and Tooth Calculus Analyses Combined. Quaternary International 255:4252.CrossRefGoogle Scholar
Babot, M. del P. 2003. Starch Grain Damage as an Indicator of Food Processing. In Phytolith and Starch Research in the Australian-Pacific-Asian Regions: The State of the Art, edited by Hart, Diane M. and Wallis, Lynley A., pp. 6982. Pandanus Books, Canberra.Google Scholar
Beresford-Jones, David G., Arce T., Susana, Whaley, Oliver Q., and Chepstow-Lusty, Alex J.. 2009. The Role of Prosopis in Ecological and Landscape Change in the Samaca Basin, Lower Ica Valley, South Coast Peru from the Early Horizon to the Late Intermediate Period. Latin American Antiquity 20:303332.CrossRefGoogle Scholar
Berquist, Stephen, Gonzalez-Macqueen, Felipe, and Jennings, Justin. 2021. Making Quilcapampa: Trails, Petroglyphs, and the Creation of a Moving Place. In Quilcapampa: A Wari Enclave in Southern Peru, edited by Jennings, Justin, Yépez Álvarez, Willy J., and Bautista, Stefanie, pp. 86130. University Press of Florida, Gainesville.Google Scholar
Bikoulis, Peter, Gonzalez-Macqueen, Felipe, Spence-Morrow, Giles, Bautista, Stefanie, Álvarez, Willy Yépez, and Jennings, Justin. 2018. Ancient Pathways and Geoglyphs in the Sihuas Valley of Southern Peru. Antiquity 92:13771391.CrossRefGoogle Scholar
Biwer, Matthew E. 2019. Colonialism, Cuisine, and Culture Contact: An Analysis of Provincial Foodways of the Wari Empire. PhD dissertation, Department of Anthropology, University of California, Santa Barbara.Google Scholar
Biwer, Matthew E., and Melton, Mallory A.. 2021. Plant Use at Quilcapampa. In Quilcapampa: A Wari Enclave in Southern Peru, edited by Jennings, Justin, Yépez Álvarez, Willy J., and Bautista, Stefanie, pp. 307349. University Press of Florida, Gainesville.CrossRefGoogle Scholar
Biwer, Matthew E., and Melton, Mallory A.. 2022. Starch Granule Evidence for the Presence of Chuño at the Middle Horizon (A.D. 600–1000) Site of Quilcapampa La Antigua, Peru. Journal of Archaeological Science: Reports 45:103604.Google Scholar
Bogaard, A., Heaton, T. H. E., Poulton, P., and Merbach, I.. 2007. The Impact of Manuring on Nitrogen Isotope Ratios in Cereals: Archaeological Implications for Reconstruction of Diet and Crop Management Practices. Journal of Archaeological Science 34:335343.CrossRefGoogle Scholar
Bonavia, Duccio. 1996. Los camélidos sudamericanos: Una introducción a su estudio. Institut Français d’Études Andines, Lima.CrossRefGoogle Scholar
Brack Egg, Antonio. 1999. Diccionario enciclopédico de plantas útiles del Perú. CBC, Cusco.Google Scholar
Browman, David L. 1974. Pastoral Nomadism in the Andes. Current Anthropology 15:188196.CrossRefGoogle Scholar
Browman, David L. 1990. Camelid Pastoralism in the Andes: Llama Caravan Fleteros and their Importance in Production and Distribution. In Nomads in a Changing World, edited by Salzman, Philip Carl and Galaty, John G., pp. 395438. Instituto Universitario Orientale, Naples.Google Scholar
Bruno, Maria C., and Hastorf, Christine A.. 2016. Gifts from the Camelids: Archaeobotanical Insights into Camelid Pastoralism through the Study of Dung. In Archaeology of Andean Pastoralism, edited by Capriles, José M. and Tripcevich, Nicholas, pp. 5565. University of New Mexico Press, Albuquerque.Google Scholar
Bryant, F. C., and Farfan, R. D.. 1984. Dry Season Forage Selection by Alpaca [Lama pacos] in Southern Peru. Journal of Range Management 37:330333.CrossRefGoogle Scholar
Budd, P., Montgomery, J., Evans, J., and Barreiro, B.. 2000. Human Tooth Enamel as a Record of the Comparative Lead Exposure of Prehistoric and Modern People. Science of the Total Environment 263:110.CrossRefGoogle Scholar
Cadwallader, Lauren, Beresford-Jones, David G., Whaley, Oliver Q., and O'Connell, Tamsin. 2012. The Signs of Maize? A Reconsideration of What δ13C Values Say about Palaeodiet in the Andean Region. Human Ecology 40:487509.CrossRefGoogle Scholar
Cagnato, Clarissa, Nicolas Goepfert, Michelle Elliott, Gabriel Prieto, John Verano, and Dufour, Elise. 2021. Eat and Die: The Last Meal of Sacrificed Chimú Camelids at Huanchaquito-Las Llamas, Peru, as Revealed by Starch Grain Analysis. Latin American Antiquity 32:595611.CrossRefGoogle Scholar
Candia, Roberto, and Dealmasso, A. D.. 1995. Dieta del guanaco (Lama guanicoe) y productividad del pastizal en la Reserva La Payunia, Mendoza (Argentina). Multequina 4:515.Google Scholar
Capparelli, Aylen, Pochettino, María Lelia, Lema, Veronica, López, María Laura, Andreoni, Diego, Ciampagna, María Laura, and Llano, Carina. 2015. The Contribution of Ethnobotany and Experimental Archaeology to Interpretation of Ancient Food Processing: Methodological Proposals Based on the Discussion of Several Case Studies on Prosopis spp., Chenopodium spp. and Cucurbita spp. from Argentina. Vegetation History and Archaeobotany 24:151163.CrossRefGoogle Scholar
Capriles, José M. 2014. Mobile Communities and Pastoralist Landscapes during the Formative Period in the Central Altiplano of Bolivia. Latin American Antiquity 25:326.CrossRefGoogle Scholar
Caro, Deborah A. 1985. “Those Who Divide Us”: Resistance and Change among Pastoral Ayllus in Ulla Ulla, Bolivia. PhD dissertation, Department of Anthropology, Johns Hopkins University, Baltimore.Google Scholar
Crowther, Alison, Michael Haslam, Nikki Oakden, Walde, Dale, and Mercader, Julio. 2014. Documenting Contamination in Ancient Starch Laboratories. Journal of Archaeological Science 49:90104.CrossRefGoogle Scholar
Cruz, Gonzalo, Pablo Ribotta, Cristina Ferrero, and Iturriaga, Laura. 2016. Physicochemical and Rheological Characterization of Andean Tuber Starches: Potato (Solanum tuberosum ssp. Andigenum), Oca (Oxalis tuberosa Molina) and Papalisa (Ullucus tuberosus Caldas). Starch 68:10841094.CrossRefGoogle Scholar
Dantas, M., Figueroa, G. G., and Laguens, A.. 2014. Llamas in the Cornfield: Prehispanic Agro–Pastoral System in the Southern Andes. International Journal of Osteoarchaeology 24:149165.CrossRefGoogle Scholar
deFrance, Susan D. 2016. Pastoralism through Time in Southern Peru. In Archaeology of Andean Pastoralism, edited by Capriles, José M. and Tripcevich, Nicholas, pp. 119138. University of New Mexico Press, Albuquerque.Google Scholar
de Haan, Stef, Burgos, Gabriela, Arcos, Jesus, Canto, Raul, Scurrah, Maria, Salas, Elisa, and Bonierbale, Merideth. 2010. Traditional Processing of Black and White Chuno in the Peruvian Andes: Regional Variants and Effect on the Mineral Content of Native Potato Cultivars. Economic Botany 64:217234.CrossRefGoogle Scholar
De Nigris, Mariana. 2004. El consumo en grupos cazadores recolectores: Un ejemplo zooarqueológico de Patagonia Meridional. Sociedad Argentina de Antropología, Buenos Aires.Google Scholar
DeNiro, Michael J., and Epstein, Samuel. 1978. Influence of Diet on the Distribution of Carbon Isotopes in Animals. Geochimica et Cosmochimica Acta 42:495506.CrossRefGoogle Scholar
DeNiro, Michael J., and Epstein, Samuel. 1981. Influence of Diet on the Distribution of Nitrogen Isotopes in Animals. Geochimica et Cosmochimica Acta 45:341351.CrossRefGoogle Scholar
Dickau, Ruth, Bruno, Maria C., Iriarte, José, Prümers, Heiko, Betancourt, Carla Jaimes, Holst, Irene, and Mayle, Francis E.. 2012. Diversity of Cultivars and Other Plant Resources Used at Habitation Sites in the Llanos de Mojos, Beni, Bolivia: Evidence from Macrobotanical Remains, Starch Grains, and Phytoliths. Journal of Archaeological Science 39:357370.CrossRefGoogle Scholar
Dufour, Elise, Goepfert, Nicolas, León, Belkys Gutiérrez, Chauchat, Claude, Jordán, Régulo Franco, and Sánchez, Segundo Vásquez. 2014. Pastoralism in Northern Peru during Pre-Hispanic Times: Insights from the Mochica Period (100–800 AD) Based on Stable Isotopic Analysis of Domestic Camelids. PLoS ONE 9(1):e87559.CrossRefGoogle ScholarPubMed
Duncan, Neil A., Pearsall, Deborah M., and Benfer, Robert A. Jr. 2009. Gourd and Squash Artifacts Yield Starch Grains of Feasting Foods from Preceramic Peru. PNAS 106:1320213206.CrossRefGoogle ScholarPubMed
Finucane, Brian, Agurto, Patricia Maita, and Isbell, William H.. 2006. Human and Animal Diet at Conchopata, Peru: Stable Isotope Evidence for Maize Agriculture and Animal Management Practices during the Middle Horizon. Journal of Archaeological Science 33:17661776.CrossRefGoogle Scholar
Flores Ochoa, Jorge A. 1968. Los pastores de Paratía: Una introducción a su estudio. Instituto Indigenista Interamericano, Mexico City.Google Scholar
Fowler, Murray E. 2010. Medicine and Surgery of Camelids. 3rd ed. Wiley-Blackwell, Ames, Iowa.CrossRefGoogle Scholar
Gifford-Gonzalez, Diane. 2018. An Introduction to Zooarchaeology. Springer, New York.CrossRefGoogle Scholar
Giovanetti, Marco A., Lema, Verónica S., Bartoli, Carlos G., and Capparelli, Aylen. 2008. Starch Grain Characterization of Prosopis chilensis (Mol.) Stuntz and P. flexuosa DC, and the Analysis of their Archaeological Remains in Andean South America. Journal of Archaeological Science 35:29732985.CrossRefGoogle Scholar
Gomez Molina, Eduardo, and Little, Adrienne V.. 1981. Geoecology of the Andes: The Natural Science Basis for Research Planning. Mountain Research and Development 1:115144.CrossRefGoogle Scholar
Gross, R., Koch, F., Malaga, I., de Miranda, A. F., Schoeneberger, H., and Trugo, L. C.. 1989. Chemical Composition and Protein Quality of Some Local Andean Food Sources. Food Chemistry 34:2534.CrossRefGoogle Scholar
Hakenbeck, Susanne E., Jane Evans, Hazel Chapman, and Fóthi, Erzsébet. 2017. Practising Pastoralism in an Agricultural Environment: An Isotopic Analysis of the Impact on the Hunnic Incursions on Pannonian Populations. PLoS ONE 12(3):e0173079.CrossRefGoogle Scholar
Hart, Thomas C. 2014. Phytoliths, Starch Grains, and Emerging Social Complexity at Tell Zeidan, Syria. PhD dissertation, Department of Anthropology, University of Connecticut, Mansfield.Google Scholar
Henry, Amanda G., Hudson, Holly F., and Piperno, Dolores R.. 2009. Changes in Starch Grain Morphologies from Cooking. Journal of Archaeological Science 36:915922.CrossRefGoogle Scholar
Henry, Amanda G., and Piperno, Dolores R.. 2008. Using Plant Microfossils from Dental Calculus to Recover Human Diet: A Case Study from Tell al-Raqā'i, Syria. Journal of Archaeological Science 35:19431950.CrossRefGoogle Scholar
Hillson, Simon. 2005. Teeth. 2nd ed. Cambridge Manuals in Archaeology, Cambridge.CrossRefGoogle Scholar
Isbell, William H. 2009. Huari: A New Direction in Central Andean Urban Evolution. In Domestic Life in Prehispanic Capitals: A Study of Specialization, Hierarchy, and Ethnicity, edited by Manzanilla, Linda R. and Chapdelaine, Claude, pp. 197219. Memoirs No. 46. University of Michigan Museum of Anthropology, Ann Arbor.Google Scholar
Izeta, A. D., Laguens, A. G., Marconetto, M. B., and Scattolin, M. C.. 2009. Camelid Handling in the Meridional Andes during the First Millennium AD: A Preliminary Approach Using Stable Isotopes. International Journal of Osteoarchaeology 19:204214.CrossRefGoogle Scholar
Jennings, Justin, Berquist, Stephen, Spence-Morrow, Giles, Bikoulis, Peter, Gonzales-Macqueen, Felipe, Yépez Álvarez, Willy J., and Bautista, Stefanie L.. 2018. A Moving Place: The Two-Millennia-Long Creation of Quilcapampa. In Powerful Places in the Ancient Andes, edited by Jennings, Justin and Swenson, Edward R., pp. 399426. University of New Mexico Press, Albuquerque.Google Scholar
Jennings, Justin, Rizzuto, Branden, and Yépez Álvarez, Willy J.. 2021. Living at Quilcapampa: Brief Occupation and Orderly Abandonment. In Quilcapampa: A Wari Enclave in Southern Peru, edited by Jennings, Justin, Yépez Álvarez, Willy J., and Bautista, Stefanie, pp. 86130. University Press of Florida, Gainesville.CrossRefGoogle Scholar
Knudson, Kelly J. 2009. Oxygen Isotope Analysis in a Land of Environmental Extremes: The Complexity of Isotopic Work in the Andes. International Journal of Osteoarchaeology 19:171191.CrossRefGoogle Scholar
Knudson, Kelly J., Emily Webb, Christine White, and Longstaffe, Fred J.. 2014. Baseline Data for Andean Paleomobility Research: A Radiogenic Strontium Isotope Study of Modern Peruvian Agricultural Soils. Archaeological and Anthropological Sciences 6:205219.CrossRefGoogle Scholar
Kuznar, Lawrence A. 2016. Andean Pastoralism and Its Effect on Economic and Social Stability in the Andes. In Archaeology of Andean Pastoralism, edited by Capriles, José M. and Tripcevich, Nicholas, pp. 1116. University of New Mexico Press, Albuquerque.Google Scholar
Leonard, Chelsea, Vashro, Layne, O'Connell, James F., and Henry, Amanda G.. 2015. Plant Microremains in Dental Calculus as a Record of Plant Consumption: A Test with Twe Forager-Horticulturalists. Journal of Archaeological Science: Reports 2:449457.Google Scholar
Liu, Li, Duncan, Neil A., Chen, Xingcan, Liu, Guoxiang, and Zhao, Hao. 2015. Plant Domestication, Cultivation, and Foraging by the First Farmers in Early Neolithic Northeast China: Evidence from Microbotanical Remains. Holocene 25:19651978.CrossRefGoogle Scholar
Madella, Marco, García-Granero, Juan José, Out, Welmoed A., Ryan, Philippa, and Usai, Donatella. 2014. Microbotanical Evidence of Domestic Cereals in Africa 7000 Years Ago. PLoS ONE 9:e110177.CrossRefGoogle ScholarPubMed
Melton, Mallory A., Biwer, Matthew E., and Panjarjian, Rita. 2020. Differentiating Chuño Blanco and Chuño Negro in Archaeological Samples Based on Metrics and Morphological Attributes. Journal of Archaeological Science: Reports 34:102650.Google Scholar
Mengoni Goñalons, Guillermo L., and Yacobaccio, Hugo D.. 2006. The Domestication of South American Camelids. In Documenting Domestication, edited by Zeder, Melinda A., Bradley, Daniel, Emshwiller, Eve, and Smith, Bruce D., pp. 228244. University of California Press, Berkeley.Google Scholar
Mickleburgh, Hayley L., and Pagán-Jiménez, Jaime R.. 2012. New Insights into the Consumption of Maize and Other Food Plants in the Pre-Columbian Caribbean from Starch Grains Trapped in Human Dental Calculus. Journal of Archaeological Science 39:24682478.CrossRefGoogle Scholar
Middleton, William D., and Rovner, Irwin. 1994. Extraction of Opal Phytoliths from Herbivore Dental Calculus. Journal of Archaeological Science 21:469473.CrossRefGoogle Scholar
Moneresinos-Tubée, Daniel B., and Mondragón, Luis P.. 2014. Flor y vegetación en tres localidades de una cuenca costeña: Rio Acarí, Provincia de Carvelí (Arequipa, Perú). Zonas Áridas 15:1130.Google Scholar
Montgomery, J., Budd, P., and Evans, J.. 2000. Reconstructing the Lifetime Movements of Ancient People: A Neolithic Case Study from Southern England. European Journal of Archaeology 3:370385.CrossRefGoogle Scholar
Moore, Katherine M. 2016. Early Domesticated Camelids in the Andes. In Archaeology of Andean Pastoralism, edited by Capriles, José M. and Tripcevich, Nicholas, pp. 1738. University of New Mexico Press, Albuquerque.Google Scholar
Murra, John V. 1960. Rite and Crop in the Inca State. In Culture in History: Essays in Honor of Paul Radin, edited by Diamond, Stanley, pp. 393407. Columbia University Press, New York.Google Scholar
Musaubach, M. Gabriela, and Berón, Mónica A.. 2017. Food Residues as Indicators of Processed Plants in Hunter-Gatherers’ Pottery from La Pampa (Argentina). Vegetation History and Archaeobotany 26:111123.CrossRefGoogle Scholar
Nigra, Benjamin T., Rosas, Augusto Cardona, Lozada, Maria C., and Barnard, Hans. 2017. Reconstructing the Built Environment of the Millo Complex, Vitor Valley, Peru. Ñawpa Pacha 37:3962.CrossRefGoogle Scholar
Pacheco Torres, Victor R., Altamirano Enciso, Alfredo J., and Guerra Porras, Emma S.. 1979. Guía osteológica de camélidos sudamericanos. Serie Investigaciones No. 4. Universidad Nacional Mayor de San Marcos, Lima.Google Scholar
Pagán-Jiménez, Jaime R. 2015. Almidones: Guía de material comparativo moderno del Ecuador para los estudios paleoetnobotánicos en el Neotrópico. Aspha Ediciones, Buenos Aires.Google Scholar
Pagán-Jiménez, Jaime R., Guachamín-Tello, Ana M., Romero-Bastidas, Martha E., and Constantine-Castro, Angelo R.. 2016. Late Ninth Millennium B.P. Use of Zea mays L. at Cubilán Area, Highland Ecuador, Revealed by Ancient Starches. Quaternary International 404:137155.CrossRefGoogle Scholar
Panarello, Héctor O., and Fernández, C. Jorge. 2002. Stable Carbon Isotope Measurements on Hair from Wild Animals from Altiplanic Environments of Jujuy. Radiocarbon 44:709716.CrossRefGoogle Scholar
Piperno, Dolores R., and Dillehay, Tom D.. 2008. Starch Grains on Human Teeth Reveal Early Broad Crop Diet in Northern Peru. PNAS 105:1962219627.CrossRefGoogle ScholarPubMed
Popenoe, Hugh, King, Steven R., Leon, Jorge, and Kalinowski, Luis Sumar. 1989. Lost Crops of the Incas: Little-Known Plants of the Andes with Promise for Worldwide Cultivation. National Academy Press, Washington, DC.Google Scholar
Reiner, Richard J., and Bryant, Fred C.. 1986. Botanical Composition and Nutritional Quality of Alpaca Diets in Two Andean Rangeland Communities. Journal of Range Management 39:424427.CrossRefGoogle Scholar
Reitz, Elizabeth J., and Wing, Elizabeth S.. 2008. Zooarchaeology. 2nd ed. Cambridge University Press, Cambridge.CrossRefGoogle Scholar
Román Godines, Oscar. 2013. El paisaje de Nieve Nieve: la chaupi yunga del Lurín. Electronic document, http://repositorio.cultura.gob.pe/handle/CULTURA/204, accessed May 10, 2021.Google Scholar
Rostworowski de Diez Canseco, María. 1981. Recursos naturales renovables y pesca, siglos XVI y XVII. Instituto de Estudios Peruanos, Lima.Google Scholar
Rumold, Claudia Ursula. 2010. Illuminating Women's Work and the Advent of Plant Cultivation in the Highland Titicaca Basin of South America: New Evidence from Grinding Tool and Starch Grain Analyses. PhD dissertation, Department of Anthropology, University of California, Santa Barbara.Google Scholar
Samec, Celeste T., Yacobaccio, Hugo D., and Panarello, Héctor O.. 2017. Carbon and Nitrogen Isotope Composition of Natural Pastures in the Dry Puna of Argentina: A Baseline for the Study of Prehistoric Herd Management Strategies. Archaeological and Anthropological Sciences 9:153163.CrossRefGoogle Scholar
Santana-Sagredo, Francisca, Schutling, Rick J., Méndez-Quiros, Pablo, Vidal-Elgueta, Ale, Uribe, Mauricio, Loyola, Rodrigo, Maturana-Fernández, Anahí, et al. 2021. “White Gold” Guano Fertilizer Drove Agricultural Intensification in the Atacama Desert from AD 1000. Nature Plants 7:152158.CrossRefGoogle ScholarPubMed
Scaffidi, Beth K., and Knudson, Kelly J.. 2020. An Archaeological Strontium Isoscape for the Prehistoric Andes: Understanding Population Mobility through a Geospatial Meta-Analysis of Archaeological 87Sr/86Sr Values from Humans, Animals, and Artifacts. Journal of Archaeological Science 117:105121.CrossRefGoogle Scholar
Scannapieco, Frank A., Torres, Guillermo, and Levine, Michael J.. 1993. Salivary α-Amylase: Role in Dental Plaque and Caries Formation. Critical Reviews in Oral Biology & Medicine 4:301307.CrossRefGoogle ScholarPubMed
Shimada, Melody, and Shimada, Izumi. 1985. Prehistoric Llama Breeding and Herding on the North Coast of Peru. American Antiquity 50:326.CrossRefGoogle Scholar
Szpak, Paul, Millaire, Jean-Francois, White, Christine D., Lau, George F., Surrette, Flannery, and Longstaffe, Fred J.. 2015. Origins of Prehispanic Camelid Wool Textiles from the North and Central Coasts of Peru Traced by Carbon and Nitrogen Isotopic Analyses. Current Anthropology 56:449459.CrossRefGoogle Scholar
Szpak, Paul, Millaire, Jean-François, White, Christine D., and Longstaffe, Fred J.. 2012. Influence of Seabird Guano and Camelid Dung Fertilization on the Nitrogen Isotopic Composition of Field-Grown Maize (Zea mays). Journal of Archaeological Science 39:37213740.CrossRefGoogle Scholar
Szpak, Paul, Millaire, Jean-Francois, White, Christine D., and Longstaffe, Fred J.. 2014. Small Scale Camelid Husbandry on the North Coast of Peru (Viru Valley): Insight from Stable Isotope Analysis. Journal of Anthropological Archaeology 36:110129.CrossRefGoogle Scholar
Szpak, Paul, White, Christine D., Longstaffe, Fred J., Millaire, Jean-François, and Vásquez Sánchez, Víctor F.. 2013. Carbon and Nitrogen Isotopic Survey of Northern Peruvian Plants: Baseline for Paleodietary and Paleoecological Studies. PLoS ONE 8(1):e53763.CrossRefGoogle ScholarPubMed
Takigami, Mai, Uzawa, K., Seki, Y., Morales Chocano, D., and Yoneda, M.. 2020. Isotopic Evidence for Camelid Husbandry during the Formative Period at the Pacopampa Site, Peru. Environmental Archaeology 25:262278.CrossRefGoogle Scholar
Thornton, E. K., deFrance, Susan, Krigbaum, J., and Williams, Patrick R.. 2011. Isotopic Evidence for Middle Horizon to 16th Century Camelid Herding in the Osmore Valley, Peru. International Journal of Osteoarchaeology 21:544567.CrossRefGoogle Scholar
Tomczyk, Weronika, Milosz Giersz, Arkadiusz Soltysiak, Kamenov, George, and Krigbaum, John. 2019. Patterns of Camelid Management in Wari Empire Reconstructed Using Multiple Stable Isotope Analysis: Evidence from Castillo de Huarmey, Northern Coast of Peru. Archaeological and Anthropological Sciences 11:13071324.CrossRefGoogle Scholar
van der, Merwe, Nikolaas, J. 1982. Carbon Isotopes, Photosynthesis, and Archaeology: Different Pathways of Photosynthesis Cause Characteristic Changes in Carbon Isotope Ratios that Make Possible the Study of Prehistoric Human Diets. American Scientist 70:596606.Google Scholar
Vining, Benjamin R. 2016. Pastoral Intensification, Social Fissioning, and Ties to State Economies at the Formative Period–Middle Horizon Transition in the Lake Suches Region, Southern Peru. In Archaeology of Andean Pastoralism, edited by Capriles, José M. and Tripcevich, Nicholas, pp. 87118. University of New Mexico Press, Albuquerque.Google Scholar
Vining, Benjamin R., and Williams, Patrick Ryan. 2020. Crossing the Western Altiplano: The Ecological Context of Tiwanaku Migrations. Journal of Archaeological Science 113:105046.CrossRefGoogle Scholar
Waldron, H. A. 1981. Postmortem Absorption of Lead by the Skeleton. American Journal of Physical Anthropology 55:395.CrossRefGoogle ScholarPubMed
Waldron, H. A. 1983. On the Post-Mortem Accumulation of Lead by Skeletal Tissues. Journal of Archaeological Science 10:3540.CrossRefGoogle Scholar
Waldron, H. A., Khera, Ashok, Walker, Gayle, Wibberley, George, and Green, Christopher J. S.. 1979. Lead Concentrations in Bones and Soil. Journal of Archaeological Science 6:295298.CrossRefGoogle Scholar
Weber, Sadie, and Price, Max D.. 2016. What the Pig Ate: A Microbotanical Study of Pig Dental Calculus from 10th–3rd Millennium BC Northern Mesopotamia. Journal of Archaeological Science: Reports 6:819827.Google Scholar
Wheeler, Jane C. 1982. Aging Llamas and Alpacas by their Teeth. Llama World 1:1217.Google Scholar
Wheeler, Jane C., Russel, A. J. F., and Redden, Hilary. 1995. Llamas and Alpacas: Pre-Conquest Breeds and Post-Conquest Hybrids. Journal of Archaeological Science 22:833840.CrossRefGoogle Scholar
Wright, Sterling L., Dobney, Keith, and Weyrich, Laura S.. 2021. Advancing and Refining Archaeological Dental Calculus Research Using Multiomic Frameworks. STAR: Science & Technology of Archaeological Research 7:1330.CrossRefGoogle Scholar
Zarrillo, Sonia, Pearsall, Deborah M., Scott Raymond, J., Tisdale, Mary Ann, and Quon, Dugane J.. 2008. Directly Dated Starch Residues Document Early Formative Maize (Zea mays L.) in Tropical Ecuador. PNAS 105:50065011.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. (a) Location of Quilcapampa and other sites mentioned in the text (Landsat imagery courtesy of NASA Goddard Space Flight Center and US Geological Survey); (b) plan of Quilcapampa showing the raised plaza, core compounds immediately to the west, and a surrounding outlying area. (Color online)

Figure 1

Figure 2. Aerial view of Quilcapampa showing the contrast between fertile river bottoms and arid upland areas. Photograph courtesy of Stephen Berquist. (Color online)

Figure 2

Figure 3. Camelid dentition and wear patterns: (a) Individual 1; (b) Individual 2; (c) Individual 3; and (d) Individual 4. (Color online)

Figure 3

Figure 4. Scatterplot of stable carbon and oxygen isotopes from enamel carbonate for Individuals 1–4.

Figure 4

Figure 5. Bar graph indicating variation of strontium values: Individual 1 (blue, solid), Individual 2 (orange, horizontal lines), Individual 3 (gray, left-diagonal lines), and Individual 4 (purple, right-diagonal lines), with the local baseline range demarcated. (Color online)

Figure 5

Figure 6. (a) Scatterplot of stable carbon and nitrogen isotopes from dentin collagen for Individuals 2–4; higher carbon isotopes are related to greater contributions from C4 plants; (b) scatterplot of stable oxygen and radiogenic strontium isotopes from enamel for Individuals 1–4.

Figure 6

Table 1. Stable and Radiogenic Isotope Values for Individuals 1–4.

Figure 7

Figure 7. Starches and phytolith recovered from dental calculus of Individuals 1–3: (a) maize-like starch granule, ACL-10424, nonpolarized light; (b) maize-like starch granule, ACL-10424, polarized light; (c) potato starch granule, ACL-10500, nonpolarized light; (d) potato starch granule, ACL-10500, polarized light; (e) potato starch granule, ACL-10501, nonpolarized light; (f) potato starch granule, ACL-10501, polarized light; (g) algarrobo starch granule, ACL-10501, nonpolarized light; (h) algarrobo starch granule, ACL-10501, polarized light; and (i) unidentified phytolith, ACL-10498, nonpolarized light. Scale bar in each micrograph is 20 μm in length.

Figure 8

Table 2. Morphological Attributes of Starch Granules and Phytoliths in Dental Calculus of Quilcapampa Camelids.

Figure 9

Figure 8. Starch granules in desiccated potato from the Quilcapampa macrobotanical assemblage: (a, c) nonpolarized lighting at 200× magnification; (b, d) polarized lighting at 200× magnification; (e) nonpolarized lighting at 400× magnification. Scale bar in each micrograph is 20 μm in length. Arrows indicate features referenced in text.

Supplementary material: File

Melton et al. supplementary material 1
Download undefined(File)
File 19.9 KB
Supplementary material: File

Melton et al. supplementary material 2
Download undefined(File)
File 14.1 KB
Supplementary material: File

Melton et al. supplementary material 3
Download undefined(File)
File 14.4 KB
Supplementary material: File

Melton et al. supplementary material 4
Download undefined(File)
File 13.7 KB
Supplementary material: File

Melton et al. supplementary material 5
Download undefined(File)
File 12.7 KB