We review the major stable carbon and nitrogen isotope studies conducted on human remains in the North American Arctic (NAA) and discuss the findings with respect to two major research themes: diachronic subsistence, and the development of food cultures across the NAA. The interpretation of stable isotope data from human bone collagen and hair keratin is complicated by issues of equifinality in addition to uncertainty arising from the high fat/high protein diets of Arctic hunter gatherers. We suggest future lines of inquiry which may help to alleviate some of these challenges. Our review of Arctic stable isotope studies shows the ongoing potential of stable isotope analysis of Arctic hunter-gatherers and faunal populations, but we include the caveat that regardless of how cutting-edge or refined the analytical method, future stable isotope studies must be contextualized with other lines of evidence from well-excavated sites, and would profoundly benefit from the incorporation of indigenous perspectives and research priorities.
Human populations settled the North American Arctic (NAA) relatively late in human history as the resource-limited terrestrial landscape prompted the development of specialized technological and cultural adaptations to extract resources from marine and riverine environments. The focus of this paper is on the Late Holocene (1000–100 BP) human occupation of Greenland, and the Canadian and Alaskan Arctic coasts. Circa 800 years BP ancestors of modern Inuit and Yupik groups, known collectively as the Thule culture, spread from northwestern Alaska eastward across the Canadian Arctic to Greenland and south to Labrador and the Quebec Lower North Shore, in some cases supplanting local Pre-Inuit groups (Friesen, 2000; Friesen & Arnold, 2008; Raghavan et al., 2014). In most of these regions, there is a direct line of genetic descent from the Thule culture to modern Inuit and Yupik populations (Raff, Rzhetskaya, Tackney, & Hayes, 2015; Raghavan et al. 2014; Tackney, Jensen, Kisielinki, & O’Rourke, 2019), however population movement within regions is known to have occurred (Friesen, Finkelstein, & Medeiros, 2019). Whitridge (2016) has pointed out the negative historical implications of the term Thule, and following from this work, we have chosen not to refer to ancestral Inuit and Yupik populations as Thule. Instead we will refer to groups occupying the NAA during the Late Holocene, but before European contact as precontact Arctic peoples, while those of the post-European contact period will be referred to by their modern names. The cultures of precontact Arctic peoples, including the Old Bering Sea, Birnik, and Punuk cultures, in addition to those known as the Thule, were characterized by the use of sled dogs and large open skin boats (umiat, sing. umiak) for transportation, sophisticated technology for harvesting and storing a variety of land and sea resources, and social systems featuring settled communities, extended trade and social networks, mortuary ceremonialism, and hierarchical interpersonal relationships (Arutiunov & Sergeev, 1990; Friesen, 2016; Savelle, 2002a; Whitridge, 1999).
In this paper we review the major stable isotope studies conducted to date on archaeological populations dating to the Late Holocene in the NAA. We consider the data with respect to research themes held in common among these works and identify the challenges most frequently cited. We describe how applications of new isotopic methods and analyses may help to refine existing interpretations and emphasize the importance of robust supporting lines of evidence, and the incorporation of indigenous perspectives and community-led research, for the interpretation and success of future stable isotope research.
Despite wide geographic separation and a diversity of marine and terrestrial environments (spanning three oceans and myriad currents, freshwater deltas, tundra and boreal forest), arctic subsistence is generally characterised by reliance on only a few primary taxa common to all regions, with variable input from other secondary taxa where they are locally common. Marine taxa include seabirds and eggs, fish found at least seasonally in near-shore environments, as well as virtually all arctic marine mammals. Most of these taxa have patchy distributions that vary seasonally. Harp seals, some narwhal and beluga, bowhead whales, some walrus populations, salmonids, and most birds practice long-distance seasonal migrations (Brice-Bennett, 1977; Lavigne, 2009; Schell, Saupe, & Haubenstock, 1989; Turner, 2014), while most other pinnipeds have preferred habitats in terms of sea ice. Thus, harbour (common) seals tend to occupy only open-water environments with access to beaches on which to haul out (including near-shore polynyas in the winter) (Woollett, 2007), and walrus, ringed seals, bearded seals, and hooded seals seek out ice-edge or pack ice environments, bringing them nearer to or farther from human settlements at different times of the year, depending on climate and currents (Stewart & Lockhart, 2004; Kovacs, 2009). Of these migratory taxa, those that tend toward gregariousness have generally been more heavily relied upon where they are present (harp seals, beluga, walrus), as they can be hunted en masse and the surplus stored for later consumption (Brice-Bennett, 1977; Turner, 2014). Marine mammals were valued as well for their secondary products, such as blubber for lamps or whale bone and baleen for tool manufacture and house construction, and pinnipeds in particular were valued for their skins, which were used in clothing, footwear, boats, house construction, and for lines (Taylor, 1974). Marine and anadromous fish species played significant roles in annual subsistence rounds in the Western Arctic, including the Aleutian Islands, coastal Western Alaska, and the Mackenzie River Delta (Betts & Friesen, 2004; Britton et al., 2018a; Coltrain, 2010; Masson-McLean et al., 2019). The presence of fish on archaeological sites in the Eastern Arctic is more sporadic due in part to taphonomic bias against delicate fish remains (Whitridge, 2001), but also due to the timing of fish runs conflicting with the availability of higher-ranked resources (Norman & Friesen, 2010). There are fewer indications that fish played an important role in human subsistence on the Labrador coast (Woollett, 2007), but anadromous fish are important to modern Inuit and Métis communities in this region (Ames, 1977).
Far fewer terrestrial taxa have been of significant economic importance, particularly prior to European contact and the adoption of trapping economies by some northern peoples. Minor taxa include freshwater fish, which vary in importance by region (Betts & Friesen, 2004; Morrison, 2000), foxes (used mainly for fur), and ground birds, but these are generally eclipsed in importance by caribou (and/or muskox in certain areas) (Betts, 2005). Caribou migrate seasonally to varying degrees and are at peak condition in the late summer/fall. Caribou were important in virtually every arctic society for their furs, which were the best (and only) choice for warm winter clothing (Betts, 2005; Stefansson, 1914).
Stable carbon isotope (δ13C) values are routinely used to distinguish between consumers of marine and terrestrial food, or between consumers of different photosynthetic groups of plants in archaeological studies (Chisholm, Nelson, & Schwartz, 1983; Tauber, 1981; Van der Merwe, 1982). In the context of the North American Arctic and Subarctic, only C3 plants and marine sources of carbon are present. Comprehensive reviews of carbon isotope dynamics in terrestrial and marine environments in the Arctic can be found in Szpak, Savelle, Conolly, and Richards (2019), or Coltrain, Tackney and O’Rourke (2016). A range of just under 10‰ (–30‰ to –22‰), has been observed in the δ13C values of Arctic and Subarctic plants (Blake, 1991; Hobbie et al., 2009; Kristensen, Kristensen, Forchhammer, Michelsen, & Schmidt, 2011; Ramsay & Hobson, 1991). These differences in baseline values are passed on to upper trophic level consumers: for example, caribou are greater consumers of lichens than other herbivorous species and as a result, tend to have higher δ13C values than other local taxa (Britton, 2010; Drucker, Hobson, Ouellet, & Courtois, 2010; Guiry, Noël, Tourigny, & Grimes, 2012; Harris et al., 2019). Marine organisms have considerably higher bone collagen δ13C values ranging from –17‰ for some seabirds to between –12‰ and –15‰ for marine mammals (Britton et al., 2013; Coltrain, Hayes, & O’Rourke, 2004; Clarke, Horstmann, de Vernal, Jensen, & Misarti, 2019; Guiry et al., 2012; Harris et al., 2019; McManus-Fry, Knecht, Dobney, Richards, & Britton, 2018; Nelson, Lynnerup, & Arneborg, 2012a; Szpak, Buckley, Darwent, & Richards, 2017; Szpak et al., 2019). Additional variation in δ13C values is also observed between nearshore/benthic areas and the pelagic zone (Sherwood & Rose, 2005), but the degree of benthic-pelagic coupling varies across the Arctic Ocean and neighbouring seas (Feder, Iken, Blanchard, Jewett, & Schonberg, 2011; Grebmeier, Cooper, Feder, & Sirenko, 2006).
Stable nitrogen isotope values (δ15N) are used to track trophic relationships in ancient and extant ecosystems as animal tissues undergo stepwise enrichment in the isotope 15N with increasing trophic level (Minagawa & Wada, 1984). Nitrogen occurs in every amino acid and undergoes considerable isotopic fractionation as amino acids sourced from diet or recycled during protein turnover and catabolism are incorporated into the body during growth or tissue maintenance (Macko, Fogel, Hare, & Hoering, 1987; O’Connell, 2017). Terrestrial plants in the Arctic have very low δ15N values, ranging from –8‰ for some evergreen trees to +1‰ for berries (Craine et al., 2009; Hobbie et al., 2009; Kristensen et al., 2011) which in turn produce low δ15N values (+1‰ to +5‰) in terrestrial herbivores, like caribou or arctic hare (Coltrain et al., 2004; Drucker et al., 2010). Marine food webs contain more trophic levels, and carnivorous marine organisms, such as seal or polar bear, have high δ15N values (+14‰ to +19‰)(Cherry, Derocher, Hobson, Stirling, & Thiemann, 2011; Szpak et al., 2017; Szpak et al., 2019).
There are occurrences of natural mummification of deceased individuals in the Arctic in which soft tissues are preserved (e.g. Lynnerup, 2015), but these occurrences are rare, and generally, bone collagen and hair keratin are the most commonly preserved human biological tissues. These tissues can act as proxies for human diet as the isotopic composition of each is derived from consumed dietary protein, and to a lesser extent, from dietary carbohydrates and lipids (Ambrose & Norr, 1993; Fernandes, Nadeau, & Grootes, 2012). The δ13C value of bulk collagen or keratin represents a weighted average of the δ13C values of constituent amino acids. Isotopic offsets between collagen and diet average +5‰ but vary with the isotopic composition of different macronutrients (Ambrose & Norr, 1993). If dietary protein has a higher δ13C value than whole dietary carbon, a greater diet-tissue isotopic offset will ensue than if dietary protein has a lower δ13C value, or a value similar to that of whole dietary carbon (Ambrose & Norr, 1993). Arctic hunter-gatherers accessed different types of marine and terrestrial foods sources, depending on local environmental conditions, therefore it is difficult to apply a blanket diet-tissue offset to all palaeodietary analyses conducted in the region. One way of circumventing this source of uncertainty is to compare human collagen δ13C values directly to faunal collagen δ13C values as experimental datasets show that the δ13C value of consumer bone collagen tends to be offset by approximately +1‰ from that of prey collagen (Bocherens & Drucker, 2003). The offset between hair keratin and collagen δ13C values is variable, but keratin tends to have a lower δ13C value as it contains fewer Glycine residues than collagen; experimental studies of modern and archaeological humans show an average offset of +1.4‰ between collagen and keratin (Robbins & Kelly, 1970; O’Connell, Hedges, Healey, & Simpson, 2001; O’Connell & Hedges, 1999).
Nitrogen is present in amino acids as NH2+ molecule bonded to a carbon skeleton. As with carbon, the δ15N value of collagen or keratin depends upon the biosynthetic pathway of amino acids, and more specifically, on the number of metabolic branches in the pathway (Macko et al., 1987; O’Connell, 2017; Petzke, Boeing, Klaus, & Metges, 2005). Isotopic fractionation resulting in a positive increase in δ15N values is associated with transfer (transamination) of the nitrogen-bearing amino group from one amino acid to another in the body’s amino acid pool (Macko et al., 1987; O’Connell, 2017). Newly synthesized proteins are enriched in 15N relative to whole dietary protein, resulting in a positive shift in δ15N values between diet and consumer. The δ15N value of proteins can be offset from that of consumed dietary protein by +2 to +6‰ (Bocherens & Drucker, 2003; DeNiro & Epstein, 1981; Minagawa & Wada, 1984; O’Connell, Kneale, Tasevka, & Kuhnle, 2012), and an average offset of +3 to +4‰ is applied in many palaeodietary analyses, including those studies conducted on the collagen and hair of humans and fauna in the Arctic (e.g. Britton et al., 2018a; Coltrain et al., 2004; Coltrain, 2009; Coltrain et al., 2016; McManus-Fry et al., 2018).
The isotopic composition of bone collagen and hair keratin reflect different periods of time in an individual’s life. Human bones begin to develop in utero and once fully matured (in early adolescence to young adulthood) undergo regular cellular maintenance through slow turnover of collagen, bioapatite, and bone cells. Stable isotope analysis of collagen produces a long-term average (often greater than 20 years) of consumed and assimilated dietary protein (Hedges, Clement, Thomas, & O’Connell, 2007). In contrast, hair keratin grows approximately one cm per month and once formed is metabolically inert (LeBeau, Montgomery, & Brewer, 2011), effectively sealing in the isotope values incorporated during growth.
Many subsistence-focused research questions in the NAA can be answered through the analysis of well-preserved zooarchaeological assemblages in tandem with other lines of archaeological and ethnographic evidence, however, there are some cases that seem especially tailored for the addition of stable isotope analysis of human tissues. Butchery practices may bias zooarchaeological assemblages (Betts & Friesen, 2013), while the contribution of taxa such as whales or shellfish to arctic diets can be difficult to estimate due to use and reuse of whale skeletal elements in dwellings and tool manufacture, and incomplete collection and quantification of shellfish remains, respectively (Claassen, 2000; Giovas, 2009; McCartney, 1980; McCartney & Savelle, 1993; Savelle, 1997). A number of stable isotope studies have been conducted on human biological tissues to address the importance of whaling to arctic peoples (Coltrain et al., 2004; Coltrain, 2009; Coltrain et al., 2016), to assess the impacts of past episodes of climate change on arctic subsistence practices (Britton et al., 2013), and to provide further information regarding the diets of individuals (Britton et al., 2018a). Britton et al. (2018a) and Tackney et al. (2016) reviewed a number of these studies and noted significant geographic patterning in the types of foods consumed by pre- and post-contact Arctic hunter gatherers. Betts and Friesen (2004) emphasize the critical role that culture plays in fostering the diversity of dietary practices across the NAA. Inuit and Yupik populations are composed of discrete peoples with distinct food cultures that developed in situ in response to local resource availability and stressors (Betts, 2005; Betts & Friesen, 2013; Britton et al., 2018a; Friesen, 1999; Friesen & Arnold, 1995). In the following section, we provide a brief review of the isotope research completed to date with a focus on how these data were integrated with other lines of archaeological evidence to address two broad, related themes in Arctic research.
Stable isotope analysis of human and faunal remains can provide long-term ecological observations that are complementary to traditional ecological knowledge and historical observations, especially if they are used in tandem with palaeoenvironmental proxies (Jones & Britton, 2019). If human isotope data are contextualized against a faunal isotope baseline (Casey & Post, 2011; Van Klinken, Richards, & Hedges, 2002), then stable isotope analysis can be used to identify shifts in the trophic level of prey, or variation in the relative contributions of marine versus terrestrial sources of protein through time. Stable isotope analysis can also act as a blunt, but independent source of verification of observations from the historical period (Jensen, 2019), for example, by identifying deviations in animal behaviour between modern and archaeological time periods (e.g. Gigleux, Grimes, Tütken, Knecht, & Britton, 2019). Diachronic studies of diet are of particular interest in Arctic and Subarctic archaeology as they can often be linked to fluctuating prey numbers, technological change, cross-cultural interactions, or environmental/climate change (Arneborg et al., 1999; Betts & Friesen, 2006; Duggan et al., 2017; Friesen et al., 2019; Hodgetts, Renouf, Murray, McCuaig-Balkwill, & Howse, 2003). Migration to new physical environments with different suites of resources may have prompted cultural and/or technological adjustments to existing subsistence practices in terms of the types of animals hunted, seasonal harvesting schedules, or technology required to access available prey in sufficient quantities.
The first large-scale stable isotope study to apply a diachronic perspective to an Arctic context was conducted by Coltrain et al. (2004), later followed up by Coltrain (2009). These works estimated the importance of whaling to pre- and post-contact Inuit communities in NW Hudson Bay through δ13C and δ15N analysis of adult skeletons and contemporaneous faunal material. Radiocarbon dating of the skeletons revealed that most individuals post-dated the earliest Inuit occupations of the region and likely lived during the period of Neo-Boreal cooling known as the Little Ice Age which stretched from the 15th to 19th centuries (Coltrain, 2009; Friesen et al., 2019). Statistical modelling of the isotope data produced several findings of note. Coltrain et al. (2004) and Coltrain (2009) argued that intra-individual variation in trophic level (as indicated by δ15N values) but not in the intake of marine protein (as indicated by δ13C values) suggested differential consumption of low-trophic level marine sources of protein, such as bowhead whale or walrus. Coltrain (2009) posited an increase in consumption of bowhead whale through time at the Silumiut and Kamarvik sites. The suggestion that bowhead whale consumption increased over the Little Ice Age is contradictory to relatively long-held beliefs in Arctic archaeology that increased ice cover during the Little Ice Age would have restricted bowhead whale movements to ice free areas, forcing an increased reliance on animals that thrive in conditions of increased sea ice cover, such as ringed seal (Schledermann, 1971, 1976). Over the same period of time, ringed seal appear to have played a consistent and prominent role in the diets of the Sadlermiut from Southampton Island, also in northwest Hudson Bay (Coltrain et al., 2004; Coltrain, 2009), but these results conflicted with ethnohistoric accounts of Sadlermiut whaling activities, and archaeological site descriptions from the 1950s (Ryan, 2011). The discrepancy between the ethnohistoric and archaeological sources and the isotopic data is difficult to reconcile here. It is possible that the site descriptions and ethnohistoric accounts may not have accurately quantified the foods actually consumed by the Sadlermiut. It is also important to note that stable isotope analysis of bone collagen largely measures consumed protein; animals that contributed mainly lipids to human diet (such as walrus and bowhead whales) may be underrepresented in bone collagen (Cherry et al., 2011; Fernandes et al., 2012). As will be discussed further below, there is still considerable uncertainty regarding how diets high in protein and fat, and low in carbohydrates will be metabolised by the human body (Newsome, Wolf, Peters, & Fogel, 2014; Wolf, Newsome, Peters, & Fogel, 2015). Further zooarchaeological and material culture analysis of Southampton Island assemblages are required, and this case serves to highlight how critical other lines of evidence are to the interpretation of stable isotope data.
The effects of past episodes of climate change, such as the Medieval Climate Anomaly (AD 950–1250), and the Little Ice Age (AD 1450–1850) on local climates and weather and by extension on lived human experience can be difficult to estimate using environmental proxies which can have variable temporal and spatial resolution, and may not line up with zones of human occupation in the Arctic (Friesen et al., 2019). Recent diachronic comparisons of human hair isotope values from the Norton Pre-Inuit site of Nash Harbour and the precontact Yupik site of Nunalleq in southwest Alaska may evidence human responses to climate change at the scale of the individual. Britton et al. (2013) demonstrated striking differences in the amount of marine protein typically consumed throughout the year between these temporally separated cultures. Norton diets at Nash Harbour were composed of a greater proportion of high trophic level marine foods while the diets of Nunalleq villagers featured mixed contributions of salmonids, marine mammals, and terrestrial protein (Britton et al., 2013; Britton et al., 2018a). The hair samples from Nash Harbour and Nunalleq were recovered from house-floor contexts and hair fragments were of approximately the same length. The isotopic differences in bulk hair samples between each site could be attributed to seasonal differences in diet relating to the period of time over which the hair grew, but the isotopic differences persisted even in sequentially sampled locks of Nash Harbour and Nunalleq hair representing approximately one year of dietary inputs, suggesting that these differences must be due to either cultural or environmental factors (Britton et al., 2013). Britton et al. (2013) attribute these differences to geographic variation in the types of resources that could be accessed between the sites, and also suggest that past periods of climate change may have further influenced prey distributions. This hypothesis received additional support from Masson-MacLean et al. (2019) as they argued that a reliance on marine, anadromous and terrestrial species would have provided the Nunalleq community with a buffer against the direct (resource stress) and indirect (social stress) influences of climate change.
The study of diet has long been linked to the efforts of past Arctic populations to regulate inter-personal relationships and control the stressors associated with increasing population density (Friesen, 1999). The analysis of archaeological and ethnographic data reveals diverse strategies for coping with social and resource stressors across the NAA that correspond to the type of resources available within the particular regions of study (Friesen, 1999; Savelle, 2002a; Whitridge, 2000). Over the course of the 21st century stable isotope analyses of human remains from a wide range of archaeological contexts are increasingly used to study the relationship between social organization and diet (e.g. Alexander, Gerrard, Gutiérrez, & Millard, 2015; Linderholm, Hedestierna Jonson, Svensk, & Lidén, 2008; Toso, Gaspar, Banha da Silva, Garcia, & Alexander, 2019). Stable isotope studies of pre-contact Arctic peoples have demonstrated regional variability in diet (reviewed in Britton et al., 2018a; Coltrain et al., 2016, and Tackney et al., 2016), providing additional support to zooarchaeological studies linking diet to ethnic identity (Betts, 2005; Betts, 2009). As the works discussed below will demonstrate, stable isotope-based approaches are particularly well-suited to characterizing intra-individual variation in diet and estimating the breadth of the social catchment area of a particular mortuary site. When used with additional lines of evidence from the archaeological record, stable isotope studies can speak to aspects of food culture, such as storage, or seasonality.
Britton et al. (2018a) measured δ13C and δ15N values of sequential samples taken from eight locks of hair recovered from sealed house floor contexts at the Nunalleq village site in southwestern Alaska to investigate how the diets of individuals varied over the period of sample growth (approximately one year). Given the seasonality of resources in the region, the relative stability of the isotopic patterns of four individuals was somewhat unexpected, but did make sense within the archaeological context, particularly when other lines of evidence from the site were considered. The presence of numerous salmon vertebrae on site, and storage vessels containing aquatic biomarkers, strongly suggested that summer salmon runs may have provided the bulk of dietary protein that some individuals consumed throughout the year, likely due to the storage of surplus salmon (Britton et al., 2018a; Farrell et al., 2014; Masson-McLean et al., 2019). Modelling of the human hair isotope data against faunal isotope data provided further supporting evidence for the role of salmon in the diets of Nunalleq villagers (Britton et al., 2013; Britton et al., 2018a). However, not all individuals consumed isotopically static diets: three locks of hair tracked an increase in either δ13C, or δ13C and δ15N that persisted for several months of growth; a fourth featured covariance of δ13C and δ15N values over a period of approximately six months; and a fifth featured a significant decrease of δ15N values, but little change in δ13C values, prompting Britton et al. (2018a) to put forward several possible explanations for the observed variation. Increasing δ13C and δ15N values probably evidenced the consumption of higher trophic level marine protein; the rising and falling δ13C and δ15N values of another individual suggested a reliance on freshwater resources, such as fish or waterfowl, during part of the year followed by increasing contributions from marine protein; and finally, falling δ15N values with static δ13C values suggested consumption of shellfish or other low trophic level marine protein sources (Britton et al., 2018a). Taken together, the diversity of dietary patterns present in only eight locks of hair has implications for individual mobility patterns, social roles and social organization at Nunalleq (Britton et al., 2018a). This study was unique for offering a glimpse into the lives of individuals, which are not always accessible using traditional archaeological methods, and is complimentary to studies of population- or community-level trends.
Nelson, Lynnerup, and Arneborg (2012b) did not initially design their study to address questions relating to Inuit diets in Greenland, but rather planned to use Inuit stable isotope data to aid in the interpretation of diachronic isotopic data sets from Greenlandic Norse skeletons. However, the resulting data offered a tantalizing glimpse into Inuit subsistence and revealed geographic and intra-population differences in the types of marine species hunted, and in the relative contribution of marine and terrestrial species to Inuit diets. For example, while diets rich in marine protein were the norm among individuals recovered from coastal sites in southwest Greenland, human bone collagen δ13C and δ15N values varied between 23 individuals recovered from the site of Assumiut (Nelson et al., 2012b). Ringed seal appeared to the predominant source of dietary protein for the majority of individuals, but one adult female and a subadult may have received greater contributions of protein from narwhal, while a second subadult appeared to consume protein with stable isotope values consistent with harp seals (Nelson et al., 2012a; Nelson et al., 2012b). In northeastern Greenland, human bone collagen values plotted along a continuum of increasing contributions of marine-derived dietary protein, and multiple dietary patterns were present at the site of Dødemandsbugten (Nelson et al., 2012b). Nelson et al. (2012b) suggested that, in general, each Inuit community occupied its own territory and did not move widely around the landscape to obtain resources, but the presence of different dietary strategies implied by outlying collagen isotope values at several sites suggested movement of certain individuals who may have spent part of their lives elsewhere (Nelson et al., 2012b).
The patterns of inter-individual differences in diet uncovered by Britton et al. (2018a) and Nelson et al. (2012b) were also found by Coltrain et al. (2016) in their isotopic study of Nuvuk, the largest pre-contact mortuary site in Alaska. Within the site, the δ13C values of adults ranged from –15.7‰ to –12.4‰ and the δ15N values ranged from +17.7‰ to +22.4‰ (Coltrain et al., 2016). Some of this range in data may be attributable to biological sex: while the mean collagen δ13C and δ15N values of biological male and female skeletons did not differ significantly, the δ15N values of male skeletons were more variable than those of females (Coltrain et al., 2016). Where osteological evidence of biological sex is available for assemblages of human remains in the Arctic, there are consistently no statistically significant differences in the mean δ13C and δ15N values of males and females (Coltrain et al., 2004; Coltrain, 2009; Coltrain et al., 2016; Nelson et al., 2012b). However, the breadth of results reported by Coltrain et al. (2016) suggests that some males may have had access to different types of marine protein, perhaps due to their involvement in different subsistence or trade activities.
In certain archaeological contexts stable carbon and nitrogen isotope ratio analysis of human biological tissues can yield important insights into past human lifeways, particularly in cases where faunal preservation is poor, or when inter- and intra-population dietary variation is under study. However, stable isotope analyses of bulk proteins in the Arctic, as elsewhere, are limited by problems of equifinality. For example, prey species may have overlapping isotope values so that relative contributions of one prey class versus another cannot be distinguished with isotope mixing models (Phillips et al., 2014), or it may not be possible to distinguish physiological influences on δ15N values from dietary inputs (e.g. Britton et al., 2018a). Additional problems occur when attempting to assign human remains to an absolute chronological framework. For many years after the adoption of radiocarbon dating, the skeletons of archaeological marine hunter-gatherers were avoided as a source of radiocarbon dates in the Arctic (e.g. Arundale, 1981; Dumond & Griffin, 2002; McGhee & Tuck, 1976; Morrison, 1989), due to the uncertainty associated with the marine radiocarbon reservoir and with estimated contributions of marine carbon to human bone collagen. While a number of authors have developed methods for estimating the contribution of marine carbon to human bone collagen (e.g. Arneborg et al., 1999; Barrett & Richards, 2004; Craig, Bondioli, Fattore, Higham, & Hedges, 2013; Raghavan et al., 2014), local deviations, termed the delta (Δ) R, in the offset between atmospheric 14C concentrations and the marine radiocarbon reservoir remain a major source of uncertainty that must be included in the calibration of 14C ages from human and marine faunal skeletal remains (Bronk Ramsey, 2008; Stuiver, 1986). A discussion of ongoing research on this topic is beyond the scope of this paper, but readers are encouraged to see Dyke et al. (2018), Krus, Jensen, Hamilton, and Sayle (2019), and Ledger, Forbes, Masson-MacLean, and Knecht (2016) for an Arctic perspective on this issue. In the following section, we elaborate on some of the issues associated with equifinality, and present recently developed areas of research that have potential applications in Arctic archaeology.
We begin by focusing on recent developments in indigenous and community-led research in Arctic communities, as further bioarchaeological research cannot proceed without input and consent from descendent communities. With the development of the National Graves and Repatriation Act (NAGPRA) in the United States, and the adoption of similar provincial legislature in Canada, many of the skeletal assemblages that were collected during the 19th and 20th centuries are being returned to Arctic communities, and most bioarchaeological studies are no longer conducted without permission from descendent groups. Through the development of community-led interdisciplinary archaeology projects, such as those at Nunalleq Village and Nuvuk in Alaska, or the Traditions and Transition project in Labrador, considerable progress has been made to incorporate the priorities of indigenous stakeholders into archaeological research design (Hillerdal, 2017; Jensen, 2012; Traditions and Transitions, 2019). Some Canadian universities, such as the University of Victoria, the University of British Columbia, and Memorial University of Newfoundland, are now developing and implementing indigenous research paradigms, but much still needs to be done to incorporate the voices and concerns of indigenous groups across the Arctic in the development of archaeological questions. The incorporation of traditional knowledge could lead to a much deeper, more nuanced understanding of local environments (past and present), and an overall better interpretation of archaeological data. For example, the development of partnerships between indigenous informants and Western scientists to study biodiversity and conservation in the north has improved the quality and scope of data regarding the ways species and arctic environments are responding to climate change and to the intensification of human exploitation of land and sea resources (Krupnik & Ray, 2007; Stevenson, 1997; Thornton & Scheer, 2012). For bioarchaeologists practicing in the NAA, such an approach would aid in building bridges between academic disciplines and indigenous communities which in turn would lead to more interesting and relevant research questions, and new ways of tackling old problems. The Inuit Tapiriit Kanatami has put forward a clear and concise guide to conducting research on Inuit lands in Canada which includes strict guidelines on the ethical conduct of researchers and open access publication of data. Compliance with published indigenous research guidelines (e.g. FNIGC, 2019; ITK, 2018) would only improve the scope and impact of future bioarchaeological studies, and the relationships between archaeologists and indigenous groups across the Arctic.
As reviewed above, the diets of archaeological Arctic hunter-gatherers were composed predominantly of protein and fats derived from marine mammals, fish, and caribou, with limited sources of carbohydrate. The incorporation of these macronutrients into human tissues is a source of uncertainty that must be considered when conducting palaeodietary analyses of arctic populations. In laboratory settings high protein diets are associated with increased direct routing of dietary amino acids to proteinaceous tissues (collagen, hair, and blood), and a lower diet-collagen δ13C offsets (Jim, Jones, Ambrose, & Evershed, 2006). Conversely, the consumption of marine protein may actually increase nitrogen isotope diet-tissue offsets (Webb, Stewart, Miller, Tarlton, & Evershed, 2016). These experimental findings may have implications for palaeodietary studies of Arctic hunter-gatherers, particular with respect to estimations of trophic level. The high marine protein diets of Arctic peoples may increase the diet-collagen δ15N offsets and render commonly used trophic discrimination factors inappropriate for this context (Hedges & Reynard, 2007). However, in most of the cases presented in this paper, the trophic discrimination factors applied to human isotope data appear to be appropriate, based on prior assumptions for the zooarchaeological and archaeological records (Coltrain et al., 2004; Coltrain, 2009; Gulløv, 2012; Nelson et al., 2012b), but further support from the application of newer generations of palaeodietary models (e.g. FRUITS [Fernandes, Grootes, Nadeau, & Nehlich, 2015]; or SIMMR [Parnell, 2016]) would be a welcome addition to Arctic stable isotope studies.
The contribution of carbon from dietary lipids to bone collagen is generally considered to be relatively minor (Fernandes et al., 2012). In other, lower latitude contexts, populations accessed wild and cultivated sources of carbohydrates that provided ready sources of energy for amino acid synthesis, however, energy sources in the Arctic are limited to seasonal, and regionally variable, contributions from greens, tubers, berries, and seaweed, with the bulk sourced from animal fats. The influence of dietary lipids, such as whale (muktuk) and seal (nuktuk) blubber, on collagen δ13C values is uncertain: experimental work with other mammals has shown flexibility in the incorporation of dietary lipids into proteinaceous tissues, prompting some researchers to urge caution when designing stable isotope studies of animals (including humans) with high lipid diets as protein-only models may misinterpret the stable isotope data (Newsome et al., 2010; Newsome et al., 2014). As stable isotope studies of arctic populations have thus far been limited to the analysis of bulk proteins (collagen and keratin), the interpretations of resulting isotope data sets have, of necessity, been quite broad. A recent analysis of polar bear blood and adipose tissue samples determined that large-bodied prey (whales and walrus) provided the greatest contribution of dietary lipids, while smaller marine mammals provided the bulk of dietary protein to bears (Cherry et al., 2011). A similar approach using human skeletal remains would be challenging as the δ13C analysis of archaeological bone lipids remains relatively unexplored (Colonese et al., 2015). Instead, the δ13C analysis of non-essential amino acids found in bone collagen or hair keratin may offer a way forward. Non-essential amino acids can be divided into two groups by biosynthetic precursor: Glucogenic amino acids (Glycine, Alanine, Serine) are synthesized from carbon precursors taken from dietary carbohydrates and lipids, while the ketogenic amino acids (Glutamate and Aspartate) can be synthesized from carbon sourced from all dietary macronutrients (Newsome et al., 2014). As sources of dietary carbohydrates are limited in most of the Arctic, glucogenic amino acids would largely reflect dietary lipid sources. Building from Cherry et al. (2011), it could then be possible, for certain hunter-gatherer populations, to model the contributions of lipid sources from, for example, bowhead whale, seal, or terrestrial sources of fat, using the δ13C values of glucogenic, and potentially ketogenic amino acids, too. Further insights could then be gained through comparison with the δ13C values of Proline which may be routed directly from dietary protein (Jim et al., 2006).
Dietary stress was proposed as a possible influence on human stable isotope values in the Arctic (Coltrain et al., 2016). During periods of nutritional stress, protein synthesis in healthy adults tends to slow, but it does not cease completely (Mekota, Grupe, Ufer, & Cuntz, 2006). When insufficient concentrations of amino acids are consumed, the body will catabolise amino acids from skeletal muscle, predominantly targeting glutamic acid and alanine, for tissue maintenance, leading to secondary enrichment in 15N of body proteins (Mekota et al., 2006; Neuberger, Jopp, Graw, Püschel, & Grupe, 2013). Fuller et al. (2005) found evidence of this phenomenon, in the form of increasing δ15N values, in modern pregnant people suffering from morning sickness. The influence of dietary stress on collagen δ13C values hypothesized by Coltrain et al. (2016) finds support in the work of Neuberger et al. (2013) who, in a study of δ13C and δ15N values in the hair of anorectic patients, posited that the catabolism of body fat would introduce 13C depleted carbon back into the body’s carbon pool, thereby reducing the δ13C value of amino acids that can use lipid-derived carbon as a substrate. Beaumont and Montgomery (2016) observed this phenomenon in dentine serial sections from Irish Famine Victims. It may be premature to assume that hunter-gatherers in the Arctic were regularly afflicted by dietary stress. While there are recorded occurrences of starvation during the post-European contact period relating to illness and modern declines in Arctic prey species (Boas, 1964; Krupnik & Chlenov, 2013), there is insufficient evidence to assume that nutritional deficits were commonplace across the Arctic during prehistory. However, osteological analyses of skeletal remains from Alaska to Labrador do report skeletal markers that may be consistent with physiological stress, such as that caused by illness, or vitamin deficiencies caused by parasitic infection, or use of non-traditional foods provided by European whaling groups (Keenleyside, 1998; Keenleyside, 1990; Way, 1978). Physiological stress should be considered as a possible source of negatively covarying δ13C and δ15N values (Beaumont, Montgomery, Buckberry, & Jay, 2015; Beaumont & Montgomery 2016; King et al., 2018), but the application of a blanket correction to palaeodietary models may not be necessary.
Arctic peoples preserved hunted and gathered food resources in a variety of ways (stored in snowpack, mixed with oil or fat, air dried, or carefully fermented) for consumption throughout the year (Friesen & Arnold, 1995; see Yamin-Pasternak, Kliskey, Alessa, Pasternak, & Schweitzer, 2014 for a modern example). In the case of large scale summer or fall hunts, such as caribou in their prime, beluga drives, salmon runs, or bowhead whales, the meat and (especially) fat these provided were often expected to last through the leanest months of winter, from February to April (Betts, 2005; Betts & Friesen, 2006, 2013; Masson-MacLean et al., 2019; Taylor, 1988). It has long been recognised that the subsistence systems of many arctic peoples fall into the category of “collecting” on the spectrum of complex hunting and gathering societies (Binford, 1980; Savelle, 2002b). This distinction, in opposition to patterns of “foraging”, is an important one in that collecting is characterised by a lower level of residential mobility, but a higher level of logistical (or task) mobility and storage of high-bulk focal resources (Betts, 2005; Binford, 1980; Stenton, 1989; Whitridge, 1999; Woollett, 2007). These collecting and storage patterns, combined with variable mobility practices, may have the effect of attenuating expected seasonal differences in isotopic composition of human tissues, even when examined at a finer scale, as suggested by Britton et al. (2018a).
Several stable isotope studies have also proposed that the process of decomposition may raise the δ15N and δ13C values of stored meat. Bada, Schoeninger, and Schimmelmann (1989) analysed the effects of artificial protein hydrolysis on the stable isotope values of modern tendon collagen. The hydrolysed protein fragments became slightly enriched in 15N, while the δ15N values of unhydrolysed protein increased by up to +20‰ (Bada et al., 1989), possibly due to selective loss of particular amino acids with lower δ15N values. Recently Yurkowski, Hussey, Hussey, and Fisk (2017) tested the effects of decomposition and the duration of cold storage on the isotope values of ringed seal meat, Greenland shark tissue, and fish, and suggested that cold storage at a consistent temperature did not have an appreciable effect on stable isotope values, however, decomposition in a closed environment increased ringed seal δ15N values by up to +2‰ (Yurkowski et al., 2017). Further experimental archaeology studies may be required, but the effect on human δ15N values would probably be minor and may only be visible in incrementally growing tissues such as hair keratin, or tooth dentine.
The faunal isotope baseline is a key component of any palaeodietary or radiocarbon study using human bone collagen as an analyte; ideally, human isotope values will be compared to a set of carbon and nitrogen isotope ratio measurements from local, contemporaneous archaeological animals (Van Klinken et al., 2002). Shifts in the δ13C and δ15N values of primary producers are known to occur through time and over geographic space, and higher trophic level animals may also modify their feeding behaviours depending on local environmental conditions or hunting pressures (Betts & Friesen, 2006; Bocherens, Grandal-d’Anglade, & Hobson, 2014; Casey & Post, 2011). Several recent studies of modern and archaeological specimens have shown the influence of climate and other environmental factors on the δ13C and δ15N values of Arctic fauna. Szpak et al. (2019) have demonstrated significant differences in the δ15N values of ringed seal populations of the Central Canadian Arctic Archipelago over the past 2000 years. Historic and modern walrus populations of the Chukchi Sea had significantly lower δ15N and δ13C values than archaeological specimens (Clark et al., 2019), findings which echoed that of an earlier study conducted on multiple species of archaeological and modern marine mammals from the same region (Szpak et al., 2017). The extensive sampling protocols of the aforementioned studies exceed the scope of most human palaeodietary studies, but they serve to highlight the possibility of temporal differences in isotope baselines that should be considered when conducting human palaeodietary analyses. To date, it is difficult to conduct statistical comparisons of archaeological faunal isotope values across the Arctic due to the varying sizes of published data sets, and incomplete reporting of the archaeological context of the faunal remains used to construct isotope baselines. The increasing popularity of stable isotope analysis as a tool for palaeoenvironmental studies may reduce the sample size disparities in the future, but archaeological palaeodiet studies must still deal with issues arising from legacy collections stored in museums in North America and in Northern Europe. Some of these issues include changes in recovery methods of faunal material between the present and early 20th century (Betts, 2016); difficulties in accessing skeletal material in distant repositories that may or may not have complete inventories; and the recovery of mixed faunal assemblages from sites with multiple, overlapping, Pre-Inuit and Inuit or Yupik contexts, a common occurrence in the NAA (Park, 1993). Sampling protocols may also introduce a bias to the isotope baseline. For example, it has been proposed that in some Arctic and Sub-Arctic regions, hunter-gatherers preferred juvenile prey to adults, and that the nursing effect on δ15N values of young prey animals may explain higher than expected δ15N values of human bone collagen, but the bones of juveniles animals are often bypassed in favour of those from mature specimens (Nelson et al., 2012b) which are considered more representative of animal populations.
Compound specific isotope analysis of amino acids liberated from archaeological specimens, such as bone collagen, hair keratin, or baleen may alleviate some of the problems associated with equifinality or isotope baselines. Essential amino acids are transferred intact from dietary protein to human tissues, allowing the δ13C and δ15N values of these amino acids to be used as tracers as negligible isotopic fractionation occurs during transfer (Fogel & Tuross, 2003; McClelland & Montoya, 2002; Popp et al., 2007). The δ13C values of essential amino acids, when combined in statistical models, can identify the ‘isotope fingerprints’ associated with different sources of primary production allowing the relative contributions of multiple foodwebs to a consumer isotope value to be characterized (Elliott Smith, Harrod, & Newsome, 2018; Larsen et al., 2009; Larsen et al., 2013; Wang et al., 2018). This method has potential for improving our understanding of arctic diets, particularly when the contributions of prey species are difficult to distinguish using bulk collagen δ13C and δ15N values alone. Two studies conducted in the past 10 years have revealed surprisingly variable δ13C values (–21.2‰ to –26.3‰) of the amino acid Phenylalanine (δ13CPhe) from 10 archaeological Inuit mummies from the Nuusuuaq Peninsula in Greenland that otherwise had relatively homogenous bulk collagen δ13C values (–13.9‰ to –12.6‰) (Honch, McCullagh, & Hedges, 2012; Raghavan, McCullagh, Lynnerup, & Hedges, 2010). This exceeds the variation in δ13CPhe values measured in the collagen of hunter-gatherers from the coast of the Baltic Sea (–25.3‰ to –24.4‰) (Webb et al., 2015), or the hair of hunter-gatherers from Chile (–24.7‰ to –20.6‰) (Mora et al., 2016). These data suggest that the individuals from Nuusuuaq were either consuming different types of marine protein, or the same type of protein, but from regions with different isotopic baselines. Further analysis of faunal specimens is of course required, but even this small dataset is evocative of the potential of compound specific carbon isotope applications to arctic contexts with respect to human palaeodiet, social organization, and palaeoenvironmental reconstructions.
Decisions surrounding breastfeeding initiation, the time at which complementary foods are introduced, and the types of foods given to infants are strongly influenced by cultural attitudes toward female bodies, child rearing, and sexual politics (Fildes, 1986; Palmer, 2009). Breastfeeding and weaning practices, and the foods accessed by children, are closely linked to infant mortality and infection (Sankar et al., 2015), population size, social and economic roles of infant caregivers, and social concepts of childhood (Fildes, 1986). Stable carbon and nitrogen isotope analysis of bone and dental collagen is commonly used to study breastfeeding and weaning practices in disparate archaeological contexts around the world (e.g. Britton et al., 2018b; Eerkens & Bartelink, 2013; Herring et al., 1998; King et al., 2018; Nitsch, Humphrey, & Hedges, 2011), but to date such studies have not been attempted in Arctic contexts. There is little published information about the breastfeeding and weaning practices of Arctic caregivers in the pre- or post-contact periods that can be used to understand the modern trajectory of infant care in the Arctic (Asuri, Ryan, & Arbour, 2011; McIsaac, 2014). Bioarchaeological studies of breastfeeding of pre- and post-contact Arctic populations would be informative of infant and maternal health in the past (Beaumont & Montgomery, 2016). Through sequential sampling and isotopic analysis of human deciduous and permanent teeth it may be possible to identify sub-annual changes in maternal and infant diets (Beaumont et al., 2015), to estimate average breastfeeding practices and by extension, commonly-held attitudes about childrearing (Britton et al., 2018b), to relate breastfeeding practices to the social and economic roles of infant caregivers (Nitsch et al., 2011), and by comparing the diets of infants and adults, gain more insight into social constructions of childhood among arctic hunter-gatherers.
Archaeological research in the North American Arctic benefits from well-preserved faunal assemblages and a rich ethnographic record with which to reconstruct past human subsistence, but stable isotope analysis of human and faunal biological tissues still has a role to play by complimenting site- and region-based analyses with data from individuals. The research discussed in this review demonstrates that stable isotope analyses of human bone collagen and hair keratin have yielded important insights into diachronic shifts in diet, food cultures, and aspects of social organization at the level of the individual, but stable isotope research still faces the same challenges in the Arctic as it does elsewhere; issues of equifinality pose a number of problems in the interpretation of isotope data sets from bulk and sequentially sampled human tissues. There is reason for hope: Arctic researchers are now combining stable isotope analysis with community-led research agendas, site-based interdisciplinary analyses, and are better able to contextualize human stable isotope data as a result. The application of additional methods, such as compound specific isotope analysis, or the isotopic analyses of breastfeeding and weaning practices, has considerable potential in the Arctic. Future research must continue to incorporate indigenous voices and research priorities as this will only improve the quality of information gleaned from archaeological and bioarchaeological investigations in the Arctic.
We would like to thank Niklas Hausmann, André Colonese, and Geoff Bailey for their work in organising the 2018 European Association of Archaeology session ‘Methodological Advances in Coastal and Maritime Archaeology’ and for inviting us to take part in this special issue. We thank Meghan Burchell and Gunilla Eriksson for reading a draft of our manuscript and for providing useful suggestions. We are very grateful to Dr. Kate Britton and two anonymous reviewers whose comments and thoughtful critiques greatly improved the quality of this paper.
This project was funded by the European Union’s framework programme for research and innovation Horizon 2020 under grant agreement No. 676154. Additional PhD funding was awarded by the Social Sciences and Humanities Research Council of Canada CGS awards to A.H. and D.E.
The authors have no competing interests to declare.
A.H. and D.E. drafted and edited the manuscript.
Alexander, MM, Gerrard, CM, Gutiérrez, A and Millard, AR. 2015. Diet, society, and economy in Late Medieval Spain: Stable isotope evidence from Muslims and Christians from Gandía, Valencia. American Journal of Physical Anthropology, 156: 263–273. DOI: https://doi.org/10.1002/ajpa.22647
Ambrose, SH and Norr, L. 1993. Experimental evidence for the relationship of the carbon isotope ratios of whole diet and dietary protein to those of bone collagen and carbonate. In: Lambert, JB and Grupe, G (eds.), Prehistoric Human Bone, 1–37. Berlin: Springer Heidelberg. DOI: https://doi.org/10.1007/978-3-662-02894-0_1
Arneborg, J, Heinemeier, J, Lynnerup, N, Nielsen, HL, Rud, N and Sveinbjörnsdóttir, ÁE. 1999. Change of diet of the Greenland Vikings determined from stable carbon isotope analysis and 14C dating of their bones. Radiocarbon, 41(2): 157–168. DOI: https://doi.org/10.1017/S0033822200019512
Arundale, WH. 1981. Radiocarbon dating in Eastern Arctic Archaeology: A flexible approach. American Antiquity, 46(2): 244–271. DOI: https://doi.org/10.2307/280207
Arutiunov, SA and Sergeev, DA. 1990. Issues of the ethnic history of the Bering Sea. Soviet Anthropology and Archaeology, 28(4): 50–77. DOI: https://doi.org/10.2753/AAE1061-1959280450
Asuri, S, Ryan, AC and Arbour, L. 2011. Report 2: Breastfeeding among Inuit in Canada. Early Inuit Child Health in Canada. Report produced for Inuit Tapiriit Kanatami. https://www.itk.ca/0wp-content/uploads/2016/07/2011-Report-Breastfeeding-among-Inuit-in-Canada.pdf [05/06/2017].
Bada, JL, Schoeninger, M and Schimmelmann, A. 1989. Isotopic fractionation during peptide bond hydrolysis. Geochimica et Cosmochimica Acta, 53(12): 3337–3341. DOI: https://doi.org/10.1016/0016-7037(89)90114-2
Barrett, JH and Richards, MP. 2004. Identity, gender, religion and economy: New isotope and radiocarbon evidence for marine resource intensification in early historic Orkney, Scotland, UK. European Journal of Archaeology, 7(3): 249–271. DOI: https://doi.org/10.1177/1461957104056502
Beaumont, J and Montgomery, J. 2016. The Great Irish Famine: Identifying starvation in the teeth of victims using stable isotope analysis of bone and incremental dentine collagen. PLoS One, 11(8): e0160065. DOI: https://doi.org/10.1371/journal.pone.0160065
Beaumont, J, Montgomery, J, Buckberry, J and Jay, M. 2015. Infant mortality and isotopic complexity: New approaches to stress, maternal health, and weaning. American Journal of Physical Anthropology, 157(3): 441–457. DOI: https://doi.org/10.1002/ajpa.22736
Betts, MW. 2005. Seven focal economies for six focal places: The development of economic diversity in the Western Canadian Arctic. Arctic Anthropology, 42(1): 47–87. DOI: https://doi.org/10.1353/arc.2011.0026
Betts, MW. 2016. Zooarchaeology and the reconstruction of ancient human-animal relationships in the Arctic. In: Friesen, TM and Mason, OK (eds.), Oxford Handbook of the Prehistoric Arctic, 81–108. Oxford: Oxford University Press. DOI: https://doi.org/10.1093/oxfordhb/9780199766956.013.8
Betts, MW and Friesen, TM. 2004. Quantifying hunter-gatherer intensification: A zooarchaeological case study from Arctic Canada. Journal of Anthropological Archaeology, 23(4): 357–384. DOI: https://doi.org/10.1016/j.jaa.2004.07.001
Betts, MW and Friesen, TM. 2006. Declining foraging returns from an inexhaustible resource? Abundance indices and beluga whaling in the Western Canadian Arctic. Journal of Anthropological Archaeology, 25(1): 59–81. DOI: https://doi.org/10.1016/j.jaa.2005.11.001
Betts, MW and Friesen, TM. 2013. Archaeofaunal signatures of specialized bowhead whaling in the Western Canadian Arctic: A regional study. Anthropozoologica, 48(1): 53–73. DOI: https://doi.org/10.5252/az2013n1a3
Binford, LR. 1980. Willow smoke and dogs’ tails: Hunter-gatherer settlement systems and archaeological site formation. American Antiquity, 45(1): 4–20. DOI: https://doi.org/10.2307/279653
Blake, W. 1991. Ratios of stable carbon isotopes in some High Arctic plants and lake sediments. Journal of Paleolimnology, 6(2): 157–166. DOI: https://doi.org/10.1007/BF00153739
Bocherens, H and Drucker, D. 2003. Trophic level isotopic enrichment of carbon and nitrogen in bone collagen: Case studies from recent and ancient terrestrial ecosystems. International Journal of Osteoarchaeology, 13(1–2): 46–53. DOI: https://doi.org/10.1002/oa.662
Bocherens, H, Grandal-d’Anglade, A and Hobson, KA. 2014. Pitfalls in comparing modern hair and fossil bone collagen C and N isotopic data to reconstruct ancient diets: A case study with cave bears (Ursus spelaeus). Isotopes in Environmental and Health Studies, 50(3): 291–299. DOI: https://doi.org/10.1080/10256016.2014.890193
Brice-Bennett, C. 1977. Land use in the Nain and Hopedale regions. In: Brice-Bennett, C, Cooke, A and Davis, N (eds.), Our Footprints are Everywhere: Inuit Land Use and Occupancy in Labrador, 97–204. Nain: Labrador Inuit Association.
Britton, K, Knecht, R, Nehlich, O, Hillerdal, C, Davis, RS and Richards, MP. 2013. Maritime adaptations and dietary variation in Prehistoric Western Alaska: Stable isotope analysis of permafrost-preserved human hair. American Journal of Physical Anthropology, 151: 448–461. DOI: https://doi.org/10.1002/ajpa.22284
Britton, K, McManus-Fry, E, Cameron, A, Duffy, P, Masson-MacLean, E, Czére, O, Smith, N, Stones, J, Winfield, A and Müldner, G. 2018b. Isotopes and new norms: Investigating the emergence of early modern U.K. breastfeeding practices at St. Nicholas Kirk, Aberdeen. International Journal of Osteoarcheology, 28(5): 1–13. DOI: https://doi.org/10.1002/oa.2678
Britton, K, McManus-Fry, E, Nehlich, O, Richards, M, Ledger, PM and Knecht, R. 2018a. Stable carbon, nitrogen and sulphur isotope analysis of permafrost preserved human hair from rescue excavations (2009, 2010) at the precontact site of Nunalleq, Alaska. Journal of Archaeological Science: Reports, 17: 950–963. DOI: https://doi.org/10.1016/j.jasrep.2016.04.015
Bronk Ramsey, C. 2008. Radiocarbon dating: Revolutions in understanding. Archaeometry, 50(2): 249–275. DOI: https://doi.org/10.1111/j.1475-4754.2008.00394.x
Casey, MM and Post, DM. 2011. The problem of isotopic baseline: Reconstructing the diet and trophic position of fossil animals. Earth-Science Reviews, 106: 131–148. DOI: https://doi.org/10.1016/j.earscirev.2011.02.001
Cherry, SG, Derocher, AE, Hobson, KA, Stirling, I and Thiemann, GW. 2011. Quantifying dietary pathways of proteins and lipids to tissues of a marine predator. Journal of Applied Ecology, 48: 373–381. DOI: https://doi.org/10.1111/j.1365-2664.2010.01908.x
Chisholm, BS, Nelson, DE and Schwarcz, HP. 1983. Marine and terrestrial protein in prehistoric diets on the British Columbia coast. Current Anthropology, 24(3): 396–398. DOI: https://doi.org/10.1086/203018
Claassen, C. 2000. Quantifying shell: Comments on Mason, Peterson, and Tiffany. American Antiquity, 65(2): 415–418. DOI: https://doi.org/10.2307/2694068
Clarke, CT, Horstmann, L, de Vernal, A, Jensen, AM and Misarti, N. 2019. Pacific walrus diet across 4000 years of changing sea ice conditions. Quaternary Research, in press. DOI: https://doi.org/10.1017/qua.2018.140
Colonese, AC, Farrell, T, Lucquin, A, Firth, D, Charlton, S, Robson, HK, Alexander, M and Craig, OE. 2015. Archaeological bone lipids as palaeodietary markers. Rapid Communications in Mass Spectrometry, 29(7): 611–618. DOI: https://doi.org/10.1002/rcm.7144
Coltrain, JB. 2009. Sealing, whaling and caribou revisited: Additional insights from the skeletal isotope chemistry of eastern Arctic foragers. Journal of Archaeological Science, 36: 764–775. DOI: https://doi.org/10.1016/j.jas.2008.10.022
Coltrain, JB, Hayes, MG and O’Rourke, DH. 2004. Sealing, whaling and caribou: The skeletal isotope chemistry of Eastern Arctic foragers. Journal of Archaeological Science, 31: 39–57. DOI: https://doi.org/10.1016/j.jas.2003.06.003
Coltrain, JB, Tackney, J and O’Rourke, DH. 2016. Thule whaling at Point Barrow, Alaska: The Nuvuk cemetery stable isotope and radiocarbon record. Journal of Archaeological Science: Reports, 9: 681–694. DOI: https://doi.org/10.1016/j.jasrep.2016.08.011
Craig, OE, Bondioli, L, Fattore, L, Higham, T and Hedges, R. 2013. Evaluating marine diets through radiocarbon dating and stable isotope analysis of victims of the AD 79 eruption of Vesuvius. American Journal of Physical Anthropology, 152: 345–352. DOI: https://doi.org/10.1002/ajpa.22352
Craine, JM, Elmore, AJ, Aidar, MP, Bustamante, M, Dawson, TE, Hobbie, EA, Kahmen, A, Mack, MC, McLauchlan, KK, Michelsen, A and Nardoto, GB. 2009. Global patterns of foliar nitrogen isotopes and their relationships with climate, mycorrhizal fungi, foliar nutrient concentrations, and nitrogen availability. New Phytologist, 183(4): 980–992. DOI: https://doi.org/10.1111/j.1469-8137.2009.02917.x
DeNiro, M and Epstein, S. 1981. Influence of diet on the distribution of nitrogen isotopes in animals. Geochimica et Cosmochimica Acta, 45(3): 341–351. DOI: https://doi.org/10.1016/0016-7037(81)90244-1
Drucker, DG, Hobson, KA, Ouellet, J-P and Courtois, R. 2010. Influence of forage preferences and habitat use on 13C and 15N abundance in wild caribou (Rangifer tarandus caribou) and moose (Alces alces) from Canada. Isotopes in Environmental and Health Studies, 46(1): 107–121. DOI: https://doi.org/10.1080/10256010903388410
Duggan, AT, Harris, AJT, Marciniak, S, Marshall, I, Kuch, M, Kitchen, A, Renaud, G, Southon, J, Fuller, B, Young, J, Fiedel, S, Golding, GB, Grimes, V and Poinar, H. 2017. Genetic discontinuity between the Maritime Archaic and Beothuk populations in Newfoundland, Canada. Current Biology, 27: 3149–3156. DOI: https://doi.org/10.1016/j.cub.2017.08.053
Dumond, DE and Griffin, DG. 2002. Measurements of the marine reservoir effect on radiocarbon ages in the Eastern Bering Sea. Arctic, 55(1): 77–86. DOI: https://doi.org/10.14430/arctic692
Dyke, AS, Savelle, JM, Szpak, P, Southon, JR, Howse, L, Desrosiers, PM and Kotar, K. 2018. An assessment of marine reservoir corrections for radiocarbon dates on walrus from the Foxe Basin region of Arctic Canada. Radiocarbon, 61(1): 67–81. DOI: https://doi.org/10.1017/RDC.2018.50
Eerkens, JW and Bartelink, EJ. 2013. Sex-biased weaning and early childhood diet among middle Holocene hunter-gatherers in Central California. American Journal of Physical Anthropology, 152(4): 471–483. DOI: https://doi.org/10.1002/ajpa.22384
Elliott Smith, EA, Harrod, C and Newsome, SD. 2018. The importance of kelp to an intertidal ecosystem varies by trophic level: Insights from amino acid δ13C analysis. Ecosphere, 9(11): e02516. DOI: https://doi.org/10.1002/ecs2.2516
Farrell, TFG, Jordan, P, Taché, K, Lucquin, A, Gibbs, K, Jorge, A, Britton, K, Craig, OE and Knecht, R. 2014. Specialized processing of aquatic resources in prehistoric Alaskan pottery?: A lipid-residue analysis of ceramic sherds from the Thule-Period site of Nunalleq, Alaska. Arctic Anthropology, 51(1): 86–100. DOI: https://doi.org/10.3368/aa.51.1.86
Feder, HM, Iken, K, Blanchard, AL, Jewett, SC and Schonberg, S. 2011. Benthic foodweb structure in the southeastern Chukchi Sea: An assessment of δ13C and δ15N analyses. Polar Biology, 34: 521–532. DOI: https://doi.org/10.1007/s00300-010-0906-9
Fernandes, R, Grootes, P, Nadeau, M-J and Nehlich, O. 2015. Quantitative diet reconstruction of a Neolithic population using a Bayesian Mixing Model (FRUITS): The case study of Ostorf (Germany). American Journal of Physical Anthropology, 158(2): 325–340. DOI: https://doi.org/10.1002/ajpa.22788
Fernandes, R, Nadeau, M-J and Grootes, PM. 2012. Macronutrient-based model for dietary carbon routing in bone collagen and bioapatite. Archaeological and Anthropological Sciences, 4(4): 291–301. DOI: https://doi.org/10.1007/s12520-012-0102-7
First Nations Information Governance Centre. 2019. The First Nations Principles of OCAP®. www.fnigc.ca/ocap [27/07/2019].
Fogel, ML and Tuross, N. 2003. Extending the limits of paleodietary studies of humans with compound specific carbon isotope analysis of amino acids. Journal of Archaeological Science, 30(5): 535–545. DOI: https://doi.org/10.1016/S0305-4403(02)00199-1
Friesen, TM. 1999. Resource structure, scalar stress, and the development of Inuit social organization. World Archaeology, 31(1): 21–37. DOI: https://doi.org/10.1080/00438243.1999.9980430
Friesen, TM. 2000. The role of social factors in Dorset-Thule interaction. In: Appelt, M, Berglund, J and Gulløv, HC (eds.), Identities and Cultural Contacts in the Arctic, 205–220. Copenhagen: Danish National Museum & Danish Polar Centre.
Friesen, TM. 2016. Pan-Arctic population movements. In: Friesen, TM and Mason, OK (eds.), Oxford Handbook of the Prehistoric Arctic. Oxford: Oxford University Press. DOI: https://doi.org/10.1093/oxfordhb/9780199766956.013.40
Friesen, TM and Arnold, CD. 1995. Prehistoric beluga whale hunting at Gupuk, Mackenzie Delta, Northwest Territories, Canada. In: McCartney, AP (ed.), Hunting the Largest Animals: Native Whaling in the Western Arctic and Subarctic, 109–126. Studies in Whaling No. 3, Occasional Publication 36. Edmonton: Canadian Circumpolar Institute Press.
Friesen, TM and Arnold, CD. 2008. The timing of the Thule migration: New dates from the Western Canadian Arctic. American Antiquity, 73(3): 527–538. DOI: https://doi.org/10.1017/S0002731600046850
Friesen, TM, Finkelstein, SA and Medeiros, AS. 2019. Climate variability of the Common Era (AD 1–2000) in the eastern North American Arctic: Impacts on human migrations. Quaternary International, in press. DOI: https://doi.org/10.1016/j.quaint.2019.06.002
Fuller, BT, Fuller, JL, Sage, NE, Harris, DA, O’Connell, TC and Hedges, REM. 2005. Nitrogen balance and δ15N: Why you’re not what you eat during nutritional stress. Rapid Communications in Mass Spectrometry, 19(8): 2497–2506. DOI: https://doi.org/10.1002/rcm.2090
Gigleux, C, Grimes, V, Tütken, T, Knecht, R and Britton, K. 2019. Reconstructing caribou seasonal biogeography in Little Ice Age (late Holocene) Western Alaska using intra-tooth strontium and oxygen isotope analysis. Journal of Archaeological Science: Reports, 23: 1043–1054. DOI: https://doi.org/10.1016/j.jasrep.2017.10.043
Giovas, CM. 2009. The shell game: Analytic problems in archaeological mollusc quantification. Journal of Archaeological Science, 36(7): 1557–1564. DOI: https://doi.org/10.1016/j.jas.2009.03.017
Grebmeier, JM, Cooper, LW, Feder, HM and Sirenko, BI. 2006. Ecosystem dynamics of the Pacific-influenced Northern Bering and Chukchi Seas in the American Arctic. Progress in Oceanography, 71: 331–361. DOI: https://doi.org/10.1016/j.pocean.2006.10.001
Guiry, EJ, Noël, S, Tourigny, E and Grimes, V. 2012. A stable isotope method for identifying transatlantic origin of pig (Sus scrofa) remains at French and English fishing stations in Newfoundland. Journal of Archaeological Science, 39(7): 2012–2022. DOI: https://doi.org/10.1016/j.jas.2012.03.004
Gulløv, HC. 2012. Archaeological commentary on the isotopic study of the Greenland Thule culture. Journal of the North Atlantic, 3: 65–76. DOI: https://doi.org/10.3721/037.004.s306
Harris, AJT, Duggan, AT, Marciniak, S, Marshall, I, Fuller, BT, Southon, J, Poinar, HN and Grimes, V. 2019. Dorset Pre-Inuit and Beothuk foodways in Newfoundland, ca. AD 500–1829. PloS One, 14(1): e0210187. DOI: https://doi.org/10.1371/journal.pone.0210187
Hedges, REM, Clement, JG, Thomas, DL and O’Connell, TC. 2007. Collagen turnover in the adult femoral mid-shaft: Modeled from anthropogenic radiocarbon tracer measurements. American Journal of Physical Anthropology, 133: 808–816. DOI: https://doi.org/10.1002/ajpa.20598
Hedges, REM and Reynard, L. 2007. Nitrogen isotopes and the trophic level of humans in archaeology. Journal of Archaeological Science, 34: 1240–1251. DOI: https://doi.org/10.1016/j.jas.2006.10.015
Herring, DA, Saunders, SR and Katzenberg, MA. 1998. Investigating the weaning process in past populations. American Journal of Physical Anthropology, 105(4): 425–439. DOI: https://doi.org/10.1002/(SICI)1096-8644(199804)105:4<425::AID-AJPA3>3.0.CO;2-N
Hobbie, JE, Hobbie, EA, Drossman, H, Conte, M, Weber, JC, Shamhart, J and Weinrobe, M. 2009. Mycorrhizal fungi supply nitrogen to host plants in Arctic tundra and boreal forests: 15N is the key signal. Canadian Journal of Microbiology, 55(1): 84–94. DOI: https://doi.org/10.1139/W08-127
Hodgetts, LM, Renouf, MAP, Murray, MS, McCuaig-Balkwill, D and Howse, L. 2003. Changing subsistence practices at the Dorset Palaeoeskimo site of Phillip’s Garden, Newfoundland. Arctic Anthropology, 40(1): 106–120. DOI: https://doi.org/10.1353/arc.2011.0012
Honch, NV, McCullagh, JSO and Hedges, REM. 2012. Variation of bone collagen amino acid δ13C values in archaeological humans and fauna with different dietary regimes: Developing frameworks of dietary discrimination. American Journal of Physical Anthropology, 148: 495–511. DOI: https://doi.org/10.1002/ajpa.22065
Inuit Tapiriit Kanatami. 2018. National Inuit Strategy on Research. https://www.itk.ca/wp-content/uploads/2018/03/National-Inuit-Strategy-on-Research.pdf [27/07/2019].
Jensen, AM. 2019. Critical information for the study of ecodynamics and socio-natural systems: Rescuing endangered heritage and data from Arctic Alaskan Coastal sites. Quaternary International, in press. DOI: https://doi.org/10.1016/j.quaint.2019.05.001
Jim, S, Jones, V, Ambrose, SH and Evershed, RP. 2006. Quantifying dietary macronutrient sources of carbon for bone collagen biosynthesis using natural abundance stable carbon isotope analysis. The British Journal of Nutrition, 95(6): 1055–1062. DOI: https://doi.org/10.1079/BJN20051685
Jones, J and Britton, K. 2019. Multi-scale, integrated approaches to understanding the nature and impact of past environmental and climatic change in the archaeological record, and the role of isotope zooarchaeology. Journal of Archaeological Science: Reports, 23: 968–972. DOI: https://doi.org/10.1016/j.jasrep.2019.02.001
Keenleyside, A. 1998. Skeletal evidence of health and disease in pre-contact Alaskan Eskimos and Aleuts. American Journal of Physical Anthropology, 107(1): 51–70. DOI: https://doi.org/10.1002/(SICI)1096-8644(199809)107:1<51::AID-AJPA5>3.0.CO;2-G
King, CL, Halcrow, SE, Millard, AR, Gröcke, DR, Standen, VG, Portilla, M and Arriaza, BT. 2018. Let’s talk about stress, baby! Infant-feeding practices and stress in the ancient Atacama Desert, Northern Chile. American Journal of Physical Anthropology, 166(1): 139–155. DOI: https://doi.org/10.1002/ajpa.23411
Kovacs, KM. 2009. Bearded Seal. In: Perrin, WE, Würsig, B and Thewissen, JGM (eds.), Encyclopedia of Marine Mammals, 97–101. Oxford: Elsevier. DOI: https://doi.org/10.1016/B978-0-12-373553-9.00028-6
Kristensen, DK, Kristensen, E, Forchhammer, MC, Michelsen, A and Schmidt, NM. 2011. Arctic herbivore diet can be inferred from stable carbon and nitrogen isotopes in C3 plants, faeces, and wool. Canadian Journal of Zoology, 89(10): 892–899. DOI: https://doi.org/10.1139/z11-073
Krupnik, I and Ray, GC. 2007. Pacific walruses, indigenous hunters, and climate change: Bridging scientific and indigenous knowledge. Deep Sea Research II: Topical Studies in Oceanography, 54(23–26): 2946–2957. DOI: https://doi.org/10.1016/j.dsr2.2007.08.011
Krus, AM, Jensen, AM, Hamilton, WD and Sayle, K. 2019. A context-appropriate approach to marine 14C calibration: Δr and Bayesian framework for the Nuvuk Cemetery, Point Barrow, Alaska. Radiocarbon, 61(3): 733–747. DOI: https://doi.org/10.1017/RDC.2019.20
Larsen, T, Taylor, DL, Leigh, MB and O’Brien, DM. 2009. Stable isotope fingerprinting: A novel method for identifying plant, fungal, or bacterial origins of amino acids. Ecology, 90(12): 3526–3235. DOI: https://doi.org/10.1890/08-1695.1
Larsen, T, Ventura, M, Andersen, N, O’Brien, DM, Piatkowski, U and McCarthy, MD. 2013. Tracing carbon sources through aquatic and terrestrial food webs using amino acid stable isotope fingerprinting. PLoS One, 8(9): 373441. DOI: https://doi.org/10.1371/journal.pone.0073441
Lavigne, DM. 2009. Harp Seal. In: Perrin, WE, Würsig, B and Thewissen, JGM (eds.), Encyclopedia of Marine Mammals, 542–546. Oxford: Elsevier. DOI: https://doi.org/10.1016/B978-0-12-373553-9.00127-9
LeBeau, MA, Montgomery, MA and Brewer, JD. 2011. The role of variations in growth rate and sample collection on interpreting results of segmental analyses of hair. Forensic Science International, 210(1–3): 110–116. DOI: https://doi.org/10.1016/j.forsciint.2011.02.015
Ledger, PM, Forbes, V, Masson-MacLean, E and Knecht, RA. 2016. Dating and digging stratified archaeology in Circumpolar North America: A view from Nunalleq, Southwestern Alaska. Arctic, 69(4): 378–390. DOI: https://doi.org/10.14430/arctic4599
Linderholm, A, Hedenstierna Jonson, C, Svensk, O and Lidén, K. 2008. Diet and status in Birka: Stable isotopes and grave goods compared. Antiquity, 82(316): 446–461. DOI: https://doi.org/10.1017/S0003598X00096939
Lynnerup, N. 2015. The Thule Inuit Mummies from Greenland. The Anatomical Record, 298: 1001–1006. DOI: https://doi.org/10.1002/ar.23131
Macko, SA, Fogel, ML, Hare, PE and Hoering, TC. 1987. Isotopic fractionation of nitrogen and carbon in the synthesis of amino acids by microorganisms. Chemical Geology: Isotope Geoscience section, 65(1): 79–92. DOI: https://doi.org/10.1016/0168-9622(87)90064-9
Masson-MacLean, E, Houmard, C, Knecht, R, Sidéra, I, Dobney, K and Britton, K. Pre-contact adaptations to the Little Ice Age in Southwest Alaska: New evidence for the Nunalleq site. Quaternary International, in press. DOI: https://doi.org/10.1016/j.quaint.2019.05.003
McCartney, AP. 1980. The nature of Thule Eskimo whale use. Arctic, 33(3): 517–541. DOI: https://doi.org/10.14430/arctic2581
McCartney, AP and Savelle, JM. 1993. Bowhead whale bones and Thule Eskimo subsistence-settlement patterns in the central Canadian Arctic. Polar Record, 29(168): 1–12. DOI: https://doi.org/10.1017/S0032247400023160
McClelland, JW and Montoya, JP. 2002. Trophic relationships and the nitrogen isotopic composition of amino acids in plankton. Ecology, 83: 2173–2180. DOI: https://doi.org/10.1890/0012-9658(2002)083[2173:TRATNI]2.0.CO;2
McGhee, R and Tuck, JA. 1976. Un-Dating the Canadian Arctic. Memorial of the Society for American Archaeology, 31: 6–14. DOI: https://doi.org/10.1017/S0081130000000745
McIsaac, KE, Lou, W, Sellen, D and Young, TK. 2014. Exclusive breastfeeding among Canadian Inuit: Results from the Nunavut Inuit Child Health Survey. Journal of Human Lactation, 30(2): 229–241. DOI: https://doi.org/10.1177/0890334413515752
McManus-Fry, E, Knecht, R, Dobney, K, Richards, MP and Britton, K. 2018. Dog-human dietary relationships in Yup’ik western Alaska: The stable isotope and zooarchaeological evidence from pre-contact Nunalleq. Journal of Archaeological Science: Reports, 17: 964–972. DOI: https://doi.org/10.1016/j.jasrep.2016.04.007
Mekota, A-M, Grupe, G, Ufer, S and Cuntz, U. 2006. Serial analysis of stable nitrogen and carbon isotopes in hair: Monitoring starvation and recovery phases of patients suffering from anorexia nervosa. Rapid Communications in Mass Spectrometry, 20(10): 1604–1610. DOI: https://doi.org/10.1002/rcm.2477
Minagawa, M and Wada, E. 1984. Stepwise enrichment of 15N along food chains: Further evidence and the relation between δ15N and animal age. Geochimica et Cosmochimica Acta, 48(5): 1135–1140. DOI: https://doi.org/10.1016/0016-7037(84)90204-7
Mora, A, Arriaza, BT, Standen, VG, Valdiosera, C, Salim, A and Smith, C. 2016. High-resolution palaeodietary reconstruction: Amino acid δ13C analysis of keratin from single hairs of mummified human individuals. Quaternary International, 436: 96–113. DOI: https://doi.org/10.1016/j.quaint.2016.10.018
Nelson, DE, Lynnerup, N and Arneborg, J. 2012a. A first isotopic dietary study of the Greenlandic Thule Culture. Journal of the North Atlantic, S3: 51–64. DOI: https://doi.org/10.3721/037.004.s305
Nelson, DE, Lynnerup, N and Arneborg, J. 2012b. Stable carbon and nitrogen isotopic measurements of the wild animals hunted by the Norse and the Neo-Eskimo People of Greenland. Journal of the North Atlantic, S3, 40–50. DOI: https://doi.org/10.3721/037.004.s304
Neuberger, FM, Jopp, E, Graw, M, Püschel, K and Grupe, G. 2013. Signs of malnutrition and starvation–Reconstruction of nutritional life histories by serial isotopic analyses of hair. Forensic Science International, 226: 22–32. DOI: https://doi.org/10.1016/j.forsciint.2012.10.037
Newsome, SD, Bentall, GB, Tinker, MT, Oftedal, OT, Ralls, K, Estes, JA and Fogel, ML. 2010. Variation in the δ13C and δ15N diet: Vibrissae trophic discrimination factors in a wild population of California sea otters. Ecological Applications, 20: 1744–1752. DOI: https://doi.org/10.1890/09-1502.1
Newsome, SD, Wolf, N, Peters, J and Fogel, ML. 2014. Amino acid δ13C analysis shows flexibility in the routing of dietary protein and lipids to the tissue of an omnivore. Integrative and Comparative Biology, 54(5): 890–902. DOI: https://doi.org/10.1093/icb/icu106
Nitsch, EK, Humphrey, LT and Hedges, REM. 2011. Using stable isotope analysis to examine the effect of economic change on breastfeeding practices in Spitalfields, London, UK. American Journal of Physical Anthropology, 146(4): 619–628. DOI: https://doi.org/10.1002/ajpa.21623
Norman, L and Friesen, TM. 2010. Thule fishing revisited: The economic importance of fish at the Pembroke and Bell sites, Victoria Island, Nunavut. Geografisk Idsskrift-Danish Journal of Geography, 110(2): 261–278. DOI: https://doi.org/10.1080/00167223.2010.10669511
O’Connell, TC. 2017. “Trophic” and “source” amino acids in trophic estimation: A likely metabolic explanation. Oecologia, 184(2): 317–326. DOI: https://doi.org/10.1007/s00442-017-3881-9
O’Connell, TC and Hedges, REM. 1999. Isotopic comparison of hair and bone: Archaeological analyses. Journal of Archaeological Science, 26: 661–665. DOI: https://doi.org/10.1006/jasc.1998.0383
O’Connell, TC, Hedges, REM, Healey, MA and Simpson, AHRW. 2001. Isotopic comparison of hair, nail and bone: Modern analyses. Journal of Archaeological Science, 28(11): 1247–1255. DOI: https://doi.org/10.1006/jasc.2001.0698
O’Connell, TC, Kneale, CJ, Tasevska, N and Kuhnle, GG. 2012. The diet-body offset in human nitrogen isotopic values: A controlled dietary study. American Journal of Physical Anthropology, 149(3): 426–434. DOI: https://doi.org/10.1002/ajpa.22140
Park, R. 1993. The Dorset-Thule succession in Arctic North America: Assessing claims for culture contact. American Antiquity, 58(2): 203–234. DOI: https://doi.org/10.2307/281966
Parnell, AC. 2016. SIMMR: A stable isotope mixing model. R Package version 0.3. https://cran.r-project.org/package=simmr.
Petzke, KJ, Boeing, H, Klaus, S and Metges, CC. 2005. Carbon and nitrogen stable isotopic composition of hair protein and amino acids can be used as biomarkers for animal-derived dietary protein intake in humans. The Journal of Nutrition, 135(6): 1515–1520. DOI: https://doi.org/10.1093/jn/135.6.1515
Phillips, DL, Inger, R, Bearhop, S, Jackson, AL, Moore, JW, Parnell, AC, Semmens, BX and Ward, EJ. 2014. Best practices for use of stable isotope mixing models in food-web studies. Canadian Journal of Zoology, 92(10): 823–835. DOI: https://doi.org/10.1139/cjz-2014-0127
Popp, BN, Graham, BS, Olson, RJ, Hannides, CCS, Lott, MJ, López-Ibarra, G, Galván-Magaña, F and Fry, B. 2007. Insight into the trophic ecology of yellowfin tuna, Thunnus albacares, from compound-specific nitrogen isotope analysis of proteinaceous amino acids. In: Dawson, TE and Siegwolf, RTW (eds.), Stable Isotopes as Indicators of Ecological Change, 173–190. Amsterdam: Academic Press. DOI: https://doi.org/10.1016/S1936-7961(07)01012-3
Raff, JA, Rzhetskaya, M, Tackney, J and Hayes, MG. 2015. Mitochondrial diversity of Iñupiat people from the Alaskan North Slope provides evidence for the origins of the Paleo- and Neo-Eskimo peoples. American Journal of Physical Anthropology, 157(4): 603–614. DOI: https://doi.org/10.1002/ajpa.22750
Raghavan, M, DeGiorgio, M, Albrechtsen, A, Moltke, I, Skoglund, P, Korneliussen, TS, Grønnow, B, Appelt, M, Gulløv, HC, Friesen, TM, Fitzhugh, W, Malmström, H, Rasmussen, S, Olsen, J, Melchior, L, Fuller, BT, Fahrni, SM, Stafford, T, Jr, Grimes, V, Renouf, MA, Cybulski, J, Lynnerup, N, Lahr, MM, Britton, K, Knecht, R, Arneborg, J, Metspalu, M, Cornejo, OE, Malaspinas, AS, Wang, Y, Rasmussen, M, Raghavan, V, Hansen, TV, Khusnutdinova, E, Pierre, T, Dneprovsky, K, Andreasen, C, Lange, H, Hayes, MG, Coltrain, J, Spitsyn, VA, Götherström, A, Orlando, L, Kivisild, T, Villems, R, Crawford, MH, Nielsen, FC, Dissing, J, Heinemeier, J, Meldgaard, M, Bustamante, C, O’Rourke, DH, Jakobsson, M, Gilbert, MT, Nielsen, R and Willerslev, E. 2014. The genetic prehistory of the New World Arctic. Science, 345(6200): 1255832. DOI: https://doi.org/10.1126/science.1255832
Raghavan, M, McCullagh, JSO, Lynnerup, N and Hedges, REM. 2010. Amino acid δ13C analysis of hair proteins and bone collagen using liquid chromatography/isotope ratio mass spectrometry: Paleodietary implications from intra-individual comparisons. Rapid Communications in Mass Spectrometry, 24(5): 541–548. DOI: https://doi.org/10.1002/rcm.4398
Ramsay, MA and Hobson, KA. 1991. Polar bears make little use of terrestrial food webs: Evidence from stable-carbon isotope analysis. Oecologia, 86(4): 598–600. DOI: https://doi.org/10.1007/BF00318328
Robbins, CR and Kelly, CH. 1970. Amino acid composition of human hair. Textile Research Journal, 40(10): 891–896. DOI: https://doi.org/10.1177/004051757004001005
Ryan, K. 2011. Comments on Coltrain et al., Journal of Archaeological Science 31, 2004 “Sealing, whaling and caribou: The skeletal isotope chemistry of eastern Arctic foragers”, and Coltrain, Journal of Archaeological Science 36, 2009 “Sealing, whaling and caribou revisited: Additional insights from the skeletal isotope chemistry of eastern Arctic foragers”. Journal of Archaeological Science, 38(10): 2858–2865. DOI: https://doi.org/10.1016/j.jas.2010.11.028
Sankar, MJ, Sinha, B, Chowdhury, R, Bhandari, N, Taneja, S, Martines, J and Bahl, R. 2015. Optimal breastfeeding practices and infant and child mortality: A systematic review and meta-analysis. Acta Paediatrica, 104(S467): 3–13. DOI: https://doi.org/10.1111/apa.13147
Savelle, JM. 1997. The role of architectural utility in the formation of zooarchaeological whale bone assemblages. Journal of Archaeological Science, 24: 869–85. DOI: https://doi.org/10.1006/jasc.1996.0167
Savelle, JM. 2002a. The Umialiit-Kariyit whaling complex and Prehistoric Thule Eskimo social relations in the eastern Canadian Arctic. Bulletin of the National Museum of Ethnology, 27(1): 159–188. DOI: https://doi.org/10.1007/978-1-4615-0543-3_4
Savelle, JM. 2002b. Logistical organization, social complexity, and the collapse of prehistoric Thule whaling societies in the central Canadian Arctic Archipelago. In: Fitzhugh, B and Habu, J (eds.), Beyond Foraging and Collecting, 73–90. New York: Springer. DOI: https://doi.org/10.1007/978-1-4612-3498-2_15
Schell, DM, Saupe, SM and Haubenstock, N. 1989. Natural isotope abundances in bowhead whale (Balaena mysticetus) baleen: Markers of aging and habitat usage. In: Rundel, PW, Ehleringer, JR and Nagy, KA (eds.), Stable Isotopes in Ecological Research, 260–269. New York: Springer.
Schledermann, P. 1976. The effect of climatic/ecological changes on the style of Thule culture winter dwellings. Arctic and Alpine Research, 8(1): 37–47. DOI: https://doi.org/10.2307/1550608
Sherwood, GD and Rose, GA. 2005. Stable isotope analysis of some representative fish and invertebrates of the Newfoundland and Labrador continental shelf food web. Estuarine, Coastal and Shelf Science, 63: 537–549. DOI: https://doi.org/10.1016/j.ecss.2004.12.010
Stefansson, V. 1914. The Stefánsson-Anderson Arctic Expedition of the American Museum: Preliminary ethnological report. New York: The Trustees. DOI: https://doi.org/10.5962/bhl.title.39990
Stuiver, M, Pearson, GW and Braziunas, TF. 1986. Radiocarbon age calibration of marine samples back to 9000 Cal Yr BP. Radiocarbon, 28(2B): 980–1022. DOI: https://doi.org/10.1017/S0033822200060264
Szpak, P, Buckley, M, Darwent, CM and Richards, MP. 2017. Long-term ecological changes in marine mammals driven by recent warming in northwestern Alaska. Global Change Biology, 24(1): 490–503. DOI: https://doi.org/10.1111/gcb.13880
Szpak, P, Savelle, JM, Conolly, J and Richards, MP. 2019. Variation in late Holocene marine environments in the Canadian Arctic Archipelago: Evidence from ringed seal bone collagen stable isotope compositions. Quaternary Science Reviews, 211: 136–155. DOI: https://doi.org/10.1016/j.quascirev.2019.03.016
Tackney, J, Coltrain, J, Raff, J and O’Rourke, D. 2016. Ancient DNA and Stable Isotopes: Windows on Arctic Prehistory. In: Friesen, TM and Mason, OK (eds.), The Oxford Handbook of the Prehistoric Arctic. Oxford: Oxford University Press. DOI: https://doi.org/10.1093/oxfordhb/9780199766956.013.3
Tackney, J, Jensen, AM, Kisielinki, C and O’Rourke, DH. 2019. Molecular analysis of an ancient Thule population at Nuvuk, Point Barrow, Alaska. American Journal of Physical Anthropology, 168(2): 303–317. DOI: https://doi.org/10.1002/ajpa.23746
Tauber, H. 1981. 13C evidence for dietary habits of prehistoric man in Denmark. Nature, 292(5821): 332–333. DOI: https://doi.org/10.1038/292332a0
Thornton, TF and Scheer, AM. 2012. Collaborative engagement of local and traditional knowledge and science in marine environments: A review. Ecology and Society, 17(3): 8. DOI: https://doi.org/10.5751/ES-04714-170308
Toso, A, Gaspar, S, Banha da Silva, R, Garcia, SJ and Alexander, M. 2019. High status diet and health in Medieval Lisbon: A combined isotopic and osteological analysis of the Islamic population from São Jorge Castle, Portugal. Archaeological and Anthropological Science, 11(8): 3699–3716. DOI: https://doi.org/10.1007/s12520-019-00822-7
Traditions and Transitions. 2019. Available at www.traditionandtransition.com [22/08/2019].
Van der Merwe, NJ. 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(6): 596–606.
Van Klinken, GJ, Richards, MP and Hedges, REM. 2002. An overview of causes for stable isotopic variations in past European human populations: Environmental, ecophysical, and cultural effects. In: Ambrose, S and Katzenberg, MA (eds.), Biogeochemical Approaches to Paleodietary Analysis, 39–63. New York: Kluwer Academic/Plenum Publishers. DOI: https://doi.org/10.1007/0-306-47194-9_3
Wang, YV, Wan, AHL, Lock, E-J, Andersen, N, Winter-Schuh, C and Larsen, T. 2018. Know your fish: A novel compound-specific isotope approach for tracing wild and farmed salmon. Food Chemistry, 256: 380–389. DOI: https://doi.org/10.1016/j.foodchem.2018.02.095
Webb, EC, Honch, NV, Dunn, PJH, Eriksson, G, Lidén, K and Evershed, RP. 2015. Compound-specific amino acid isotopic proxies for detecting freshwater resource consumption. Journal of Archaeological Science, 63: 104–114. DOI: https://doi.org/10.1016/j.jas.2015.08.001
Webb, EC, Stewart, A, Miller, B, Tarlton, J and Evershed, RP. 2016. Age effects and the influence of varying proportions of terrestrial and marine dietary protein on the stable nitrogen-isotope compositions of pig bone collagen and soft tissues from a controlled feeding experiment. STAR: Science and Technology of Archaeological Research, 2(1): 54–66. DOI: https://doi.org/10.1080/20548923.2015.1133121
Whitridge, PJ. 2001. Zen fish: A consideration of the discordance between artifactual and zooarchaeological indicators of Thule Inuit fish use. Journal of Anthropological Archaeology, 20(1): 3–72. DOI: https://doi.org/10.1006/jaar.2000.0368
Whitridge, PJ. 2016. Classic Thule (Classic Precontact Inuit). In: Friesen, TM and Mason, OK (eds.), The Oxford Handbook of the Prehistoric Arctic. Oxford: Oxford University Press. DOI: https://doi.org/10.1093/oxfordhb/9780199766956.013.41
Wolf, N, Newsome, SD, Peters, J and Fogel, ML. 2015. Variability in the routing of dietary proteins and lipids to consumer tissues influences tissue-specific isotopic discrimination. Rapid Communications in Mass Spectrometry, 29(15): 1448–1456. DOI: https://doi.org/10.1002/rcm.7239
Woollett, JM. 2007. Labrador Inuit subsistence in the context of environmental change: An initial landscape history Perspective. American Anthropologist, 109(1), 69–84. DOI: https://doi.org/10.1525/aa.2007.109.1.69
Yamin-Pasternak, S, Kliskey, A, Alessa, L, Pasternak, I and Schweitzer, P. 2014. The rotten renaissance in the Bering Strait: Loving, loathing, and washing the smell of foods with a (re)acquired taste. Current Anthropology, 55(5): 619–646. DOI: https://doi.org/10.1086/678305
Yurkowski, DJ, Hussey, AJ, Hussey, NE and Fisk, AT. 2017. Effects of decomposition on carbon and nitrogen stable isotope values of muscle tissue of varying lipid content from three aquatic vertebrate species. Rapid Communications in Mass Spectrometry, 31(4): 389–395. DOI: https://doi.org/10.1002/rcm.7802