New Records and Observations on Paleo-American Artifacts from Cerro Largo, Northeastern Uruguay and a Peculiar Case of Reclaimed Fishtail Points ()
1. Introduction
In scientific research about humankind, the evolution, dispersion and colonization of the world is one of the most fascinating and intriguing anthropological and archaeological issues (Gamble, 1996; Akazawa and Szathmary, 1999, Liu et al., 2006) . In this process, initiated in the terminal Miocene at about 5 million years ago, the Americas were the last colonized continents during the Late Pleistocene, in a time span subject to debate (Adovasio and Page, 2002, Meltzer, 2009) . However, an indubitable fact is that during the last millennium of the Pleistocene at ~11,000 - 10,000 uncalibrated radiocarbon years B.P. (~11 - 10 RCYBP hereafter) the New World was populated from Beringia to Tierra del Fuego (Graf et al., 2013; Nami, 2014a) .
A primary evidence to assess Paleo-American problems is lithic remains. They provide diverse clues regarding the human dispersion in both hemispheres of the New World. To understand general and particular issues of Late Pleistocene human groups, stone tools, mainly projectile points from those times have been subjected to a broad range of investigations. They have been useful in examining the variability of patterns at different localities; and allow the observation of numerous issues concerning their reduction sequences, morphology and function ( Rondeau, 2009; Bradley et al., 2010; Jennings, 2008; Shott, 2013; White, 2013 ; and many others). Beyond, strictly technological issues, projectile points are also useful to cope with topics related with studies on technological organization, mobility and social networks of diverse traditional societies (Wiessner, 1983, Amick, 1995, 1996, Nami et al., 2015) .
Clovis, the oldest Paleoindian fluted point, had an extraordinary dispersion through North America. Similarly, in South America, the “fishtail”, “Fell’s cave”, or just “Fell” projectile point is a wide-spread Paleo-American marker dated between ~11 - 10 RCYBP (Nami, 2007: Table 1, Dillehay, 2011: Appendix one, Prates et al., 2013) .
To discern colonization events and further New World socio-cultural developments, since the early 1980s we have performed a research program directed to deepening the knowledge and understanding of the morphological variation, technology and function of early stone tools. Particular focus was made on the fishtail points and other artifacts (Nami, 2007, 2010a, 2013; Nami and Castro, 2014) . As part of these investigations, this paper reports new data obtained on Paleo-American lithic remains from Cerro Largo (CL) department, northeastern Uruguay (Figure 1).
2. Archaeological Remarks
Located in southeastern South America, Uruguay Republic is divided into 19 departments. Covering a surface area of 13,648 km2, Cerro Largo (32˚22'5"S, 54˚10'4"W) is surrounded by fluvial courses acting as natural borders.
The archaeology of Cerro Largo (CL, hereafter) is mainly known from the Holocene mounds called Cerritos (Baeza et al., 1980, Cabrera Perez, 2005) . They are distributed from south Brazil to northeastern Argentina (Bonomo, 2012, García, 2012) . In eastern Uruguay they were extensively studied at Rocha department (Iriarte et al., 2004; Iriarte, 2006) .
Figure 1. Map of South America and the location of Cañada de Aceguá (CA), Paso Centurión (PC), Paso Taborda (PT), and Paso La Catumbera (PLC) locales in the Cerro Largo department showed with a square in the map of Uruguay (after Google Maps, 2014).
During the last years the Uruguayan Paleo American record have been of increasing interest for many authors (Suárez, 2009, Castiñeira et al., 2011, López Mazz, 2013, Meneghin, 2015) . Their research is made with remains from buried and surface records. Significant evidence of Paleo-American vestiges has been witnessed by the fishtail points finds. In this regard, the Uruguayan territory has one of the highest densities in South America. Except a few pieces, most of them are surface discoveries which are curated in public and private collections. Resulting from different causes, collectors with different attitudes are a widespread phenomenon. The study of their collections must be carefully made, especially with concerns about the specimens’ origin and authenticity (Chase et al., 1988, Femenías et al., 2011) . Being aware of this issue, from a technological perspective, artifacts from different kind of collections are useful for discussing diverse archaeological topics (e.g. Castiñeira et al., 2011; López Mazz, 2013 ). Thus, good will between private collectors and professional archaeologists allows understanding and depth of study on diverse aspects of regional lithic technology (Nami, 2013) . Continuing this research across Uruguay, I examined a significant Paleo-American sample (n = 21) from the collections of Mr. J. Rendo (Montevideo city) and the Museo Histórico Regional de Cerro Largo (MHRCL), Melo city.
The only previously reported Paleoindian find from CL was the fishtail point found by Mr. C. Etcheverry in Cañada de Aceguá (CA, Figure 2(a)), a small creek situated in the border with Brazil (Schobinger, 1974: figure 3; Bosch et al., 1980: figure 17) . The new artifacts reported here come from known and unknown sites and/or localities. They are as follows:
Paso Taborda (PT) is located on the main course of Bañados de Medina creek, at 15 km SE of Melo city (Figure 1). There, when the water level was down, archaeological and paleontological finds occured on a clay surface. A large number of artifacts, mainly projectile points come from this site, among them, three Fell pieces.
Paso Centurión (PC) is a sandy area on the Yaguarón River at 52 km north of Melo on the Brazilian border (Figure 1). Except the exemplar illustrated in Figure 3(a), formerly in the Mr. C. Echeverry collection, the remaining ones were collected by Mr. Ramón Bazz, who made a collection of artifacts found in the surface during the first half of the past century. By their quality, it seems that he was highly selective with the gathered objects. Most of them are entire projectile points and other outstandingly specimens. Remarkable is the significant number of fishtail heads (n = 16).
Tacuarí river (TR) is placed in the south of CL. The only Fell point found there come from Paso La Catumbera (Figure 1).
The provenience of the remains curated at the MHRCL is unknown. However, they add three pieces to the Uruguayan Paleoindian record. (Nami, 2015), one of them, a Paleo-American point.
3. Analysis, Observations and Results
During the last years research advances allowed deeper understanding of the fishtail point’s attributes and morphological variations (Nami, 2013, 2014a) . Many specimens from PC belong to the lanceolate variety (e.g. Figures 3(b)-(d)) with narrow blades, stems with parallel concave or incurvate borders, and concave base with pointed basal corners or ears (sensu Turner and Hester, 1985; Nami, 2014a: figure 25 4b ). Remarkably is their similarity with other fishtails observed in several Uruguayan places, such as El Puente, Cacique and Carpintería creeks (Nami, 2013: figure 3m, p, 4b, o) . Similar pieces have been found in other Southamerican locales; for instance, Dos Amigos, Argentina (Flegenheimer et al., 2013: figure 21-6: 13) and Cueva del Medio (Nami, 2014a: figure 22i) . One specimen from PC and the one curated at MHRCL have broad blades with convex borders, rounded shoulders and slightly contracted stems with concave borders (Figure 3(a)). Several lanceolate exemplars from PC display pointed basal corners (Figures 3(b)-(d), Figure 3(l) and Figure 3(m)), a feature also recognized in other Uruguayan Fell points such as the one from Paso de la Cruz and Laguna Negra at Durazno and Rocha departments respectively (Figure 4(b) and Figure 4(c)). A notable preform of this sort of variety with a clear basal beveled platform for fluting is exhibit in Figure 4(a). Remarkable is the similarity of the specimen exhibited in Figure 3(j) with those found at Cueva del Medio, Chile (Nami, 1987: Figure 16b; Nami and Heusser, 2015: Figure 3b) . In most pieces the stems’ bases were shaped by short pressure retouch. The specimen showed in Figure 3(e) has long flutes on both faces. Its thickness is slightly thicker than many fishtail points; probably intentionally preformed for fluting by direct percussion flaking. After flute detachment the base was shaped by short pressure retouch. Southamerican fishtail points show diverse basal treatments (Nami, 2003, 2014a) and by comparison with other alternatives, fluting is present on only a small amount of pieces. Flutes were obtained on diverse materials, such as black volcanic rocks (Bird, 1969) , quartzite
Figure 2. Fell points described in text and edge details of the reclaimed pieces as end-scrapers. (a) CA; (b)-(d) PT; (e) TR; (f) Unknown origin.
(Nami, 2010a: figure 2 ll) , and quartz (Briceño Rosario, 1999: figure 17; Nami, 2010a: figure I f) but most on optimal rocks, such as obsidian (Mayer-Oakes, 1986: figure 37-38; Nami, 1992, 2010a: figure I h-i; 2014b: figure 16-18, 25) , and flint-like material (Díaz Rodríguez, 2008: figure 2; Nami, 2010a: figure I a-d; 2013: figure 3l, q, Flegenheimer et al., 2013: figure 21.6: 12, Loponte et al., 2015: figure 2, 5) .
According to longitudinal cross-sections observed in Figure 2, Figure 3, the thicker part of each piece is randomly located in different places. Maximum thickness may be near the tip, the center, the blade/stem intersection, and/or the stem. This fact is also observed in other pieces throughout Latin America (e.g. Bosch et al., 1980; Nami, 2013 ).
Figure 3. Fishtail points from PC (except when is clearly expressed in the acknowledgements section, all the photographs are by the author).
The examined fishtails were manufactured employing thin flake-blanks and thinned bifaces made from thicker blanks. The former are visible in pieces from CA (Figure 2(a)), PC (Figure 3(a)), PT (Figure 2(b)), and TR (Figure 2(e)). One of the clearest examples is the one from CA that shows remains of the flake’s ventral face. Except in the distal part were retouches are deeper, it was mostly finished by short pressure retouch ~4 - 5 by ~5 mm wide and depth in both faces. Usually, for final shaping this kind of short and/or marginal retouch is bifacially applied with diverse continuity; hence the ventral face of the flake-blank is visible. Several pieces were made mostly by percussion (Figures 3(f)-(h)); and many finished by short pressure retouches at PC, and MHRCL (e.g. Figure 2(f), Figures 3(a)-(d), Figure 3(i)). This kind of production was a regular pattern among hunter-gatherers using these points. Pieces of similar manufacture were found in Ecuador (Mayer-Oakes, 1986, Nami, 2014b) , Chile (Bird, 1969: figure 2a, 3f) , Argentina (Martínez, 2001, Laguens et al., 2007, Patané Araoz and Nami, 2014) , Brazil (da Silva Lopes and Nami, 2011, Loponte et al., 2015) , and Uruguay (Nami, 2013: figure 3p, 4b, d) . Also, longitudinal and transversal cross-sections are generally plano-convex due to the use of thin flakes. In PT and PC the flake-scars underlying the short pressure retouches that finished the points suggest the use of bifacial thinning from thicker blanks (Figures 3(f)-(h), Figure 4(d)-(g)) widely documented in several sites across South America (Nami, 2013, 2014b) .
Once the finished product was used, they generally subjected to resharpening. In the case of hafted implements, resharpening is usually done while it is still in the handle (e.g. Holmes, 1919: figures 172, 174-175; Callahan, 1981: figures 17-18 ). In Fell points this is detectable when the blade form and symmetry is highly modified; retouch does not follow the remaining original pattern that finished the point, and/or the borders are strongly rounded or do not have enough mass to continue the task. According to the lack of mass in the blade that allows continued resharpening, it was catalogued as: 1) low or minimum: the blade was a little modified in
Figure 4. Fell points from different Uruguayan locales. (a)-(c) lanceolate variant. (a) Preform from Cerros Azules; (b) Paso de La Cruz; (c) Laguna Negra; (d)-(g) with edge-to-edge and/or overshot flake scars. (d) Baigorria dam; (e) Merin lagoon; (f) La Palomita; (g) Buena Vista hill.
its symmetry; 2) medium: despite some modification the blade has some mass to continue its useful life; finally, 3) intense, maximum or saturated: the blade does not have enough mass to bear continued reworking, hence, the piece is discarded (Nami, 2013) . Having in mind Fell points with little or no resharpening (Figure 2a, 3a; Nami, 2013 : figures 3g, r, 4k, l; 2014a: figures 19-20), specimens from PC show low (Figure 3(i)), medium (Figure 3(d), Figure 3(j)) and saturated resharpening (Figure 3(m) and Figure 3(n)), facts also observed in other Uruguayan and Southamerican examples (Nami, 2013: figures 3b, f, o, 4c; Nami, 2014b) .
Recycle Fell points are common; however, they are just now being recognized as a part of the Paleo-American technological behavior (see Loponte et al., 2015 for a discussion about this topic). As a process to transform discarded materials, recycling is considered as re-edging the blade of a fishtail point to create a new artifact different with a different function from that for which it was manufactured. Recycling can be performed by the members of the socio-cultural system that produced it or, by others that acquired a point as an abandoned piece from an archaeological context; these are considered reclaimed artifacts (Schiffer, 1987, 99-ss) . In this regard, two fishtails from PC show one beveled concave border (Figure 3(o) and Figure 3(p)). In South Brazil and Uruguay this is a fairly common feature of the stemmed Holocene points, called “sickles” or “foices” or “tipo hoz” (Baeza et al., 2001) and “drill” or “concave side-scraper” (Taddei, 1987: figures 21: 4-5, 24, 13) . Also in PT there are three fishtails recycled as end-scrapers (Figures 2(b)-(d)), an unknown aspect of Paleo-Ame- rican technological behavior.
Except few specimens recorded in the border of northern Patagonia in Argentina (Nami, 1984: 89, 7) , in the southern cone of South America the re-use of projectile points as end-scrapers is a rare fact. However, in southern Brazil and Uruguay there are stemmed points recycled in this manner. Actually, PT yielded Holocene points recycled in the same way (Figure 5), a phenomenon existing in nearby sites. Taddei (1980: figure XII 25-26, 1987, 24: 4) illustrated points recycled as end-scraper and graver (sensu Turner and Hester, 1985 ) from Paso del Puerto, Uruguay. Cerrito Dalpiaz rockshelter (southeastern Brazil) yielded a stratigraphic record with stemmed projectile points. From the cultural-history perspective, in Cerrito Dalpiaz sequence, they characterize the “period II” dated at ~6.0 - 4.2 RCYBP, attributed to the “Umbu tradition” (Dias, 2007, Bueno et al., 2013) . Interestingly, “stemmed scrapers” which are obviously recycled points were reported from that context (Miller, 1969: figure 8 l-n, o’) and other sites ascribed to the “Rio Pardinho phase” of the same archaeological construct (Schmitz, 1987: figure 19a-e) . Hence, due to the compatibility with the recycling behavior observed in the aforementioned artifacts, it may be suggested that the scraping tools produced on fishtail heads were made by post-Pleistocene local hunter-gatherers who collected the points from archaeological sites during the early and middle Holocene. At the present, the evidence shows that South American foragers who employed fishtails did not practice this kind of recycling for making end-scrapers, although the use and/or re-use of Fell points in other functions might also have occurred during the last millennium of the Pleistocene. Actually, currently it is possible to propose that besides projectile tips, the morphology of some Fell points suggests their reuse as knives or lateral scraping tools. As shown in Figures 6(b)-(d), some Uruguayan specimens show a beveled border suggesting another form or resharpening; also there are pieces with asymmetrical blades with one straight or slightly convex border and/or convex ends insinuating a similar situation. Additionally, this fact was observed in other locales of South America, such as the Ilaló region, Ecuador (Figure 6(a)); Cerro El Sombrero, Argentina (Flegenheimer et al., 2009) ; Fell’s cave (Figure 6(e)), and Magallanes province (Figure 6(f)), Chile.
The examined fishtails were made with highly selected rocks. At PC and PT very good quality gray, dark gray (Figure 2(b) and Figure 2(c)), and very fine black material (Figure 3(j)) was used. Many of them are respectively comparable with Georgetown flint, Onondaga, Munsungan lake and Fort Payne chert from North America. In PC, several specimens are likely limestone with small impurities and alveolus observed with magnifying glass of 10× and 20× (Figures 3(b)-(d), Figure 3(i), Figures 3(l)-(n)). Probably, some of them were affected by chemical alterations, and consequently developed clear tones on the surface (Nami, 2013: Figure 3d, 9d) . Uru-
Figure 5. End-scrapers made on recycled projectile points by Holocene hunter-gatherers at PT.
Figure 6. Reworked Fell points from different Southamerican locales. (a) Ilaló region; (b) Yi river; (c) Probably San Gregorio de Polanco; (d) Unknown origin, Uruguay; (e) Fell’s cave; (f) Magallanes province (redrawn after Bahamondes and Jackson 2006 ).
guayan limestones have different origins (Martínez et al., 1997) , and the ones with microfossils were classified as silcrete (Flegenheimer et al., 2003) . Experiments using these rocks show that they have good to excellent flaking qualities and heat treatment improves some of them (Nami, 2010a) . The piece depicted in Figure 2(d), probably is a heat-treated petrified wood, with available sources in CL.
Table 1 summarizes salient information concerning origin, raw materials, condition and significant data of each exemplar reported in this paper.
4. Summary and Conclusions
New data on Paleo-American remains from NE Uruguay allowed deepened on several archaeological topics. They added new light on the earliest lithic assemblages and stone tool behavior during the colonization of southeastern South America.
The fisthail record from CL shows strong formal variability, such as has been observed in Central and South America in general, and in the southern cone in particular (Nami, 2013, 2014b, Flegenheimer et al., 2015) . Based on ethno-archaeological baselines (Politis et al., 2013) , it may suggest that some morphological and dimensional differences among Fell points might reflect their employment by different age groups (i.e. kids-adults) and/or
Table 1. Salient morphological and technological attributes of the Fell points reported in this paper. Note: All the measurements are given in mm, *: Not given, /: Separates the maximum thickness present in a minor portion of the piece and the minimum that prevail in the totality of the artifact, L: Lengh, W: Width, T: Thickness, (): indicates fractured piece, †: Not observable, x: Reclaimed point. The blank was only reported when was clearly observed. Measurements of piece 1 was taken from Bosch et al. (1980) and calculated from the scale.
their use on different preys.
To date, along with Arroyo Cacique (Nami, 2013) , PC is the surface site that has yielded the greatest number of Fell points in Uruguay. There, the lanceolate variety with incurvate stem and concave base seems to be a recurrent form. In PT and PC several Fell heads were reworked as end-scrapers and beveled pieces with concave borders. This probably constitutes a peculiar case of lithic recycling and reclaiming of fishtail points by Holocene human groups.
Like other late Pleistocene Homo sapiens hunter-gatherer lithic assemblages (Kuhn, 1992, Vaquero et al., 2012) , those with fishtail points include both curated and expedient tools (sensu Binford, 1979 ). Fishtails were extremely curated artifacts, and occasionally recycled as knives and/or scraping tools by their makers. Ground artifacts, such as discoidals and well made bone tools (Nami, 2010b) also suggest curated strategies. Hence, an expectation of finding both expedient and curated technologies in assemblages spanning the last millennium of the Pleistocene in the southern cone is a logical conclusion.
The west of CL belongs to the Negro river basin that yielded the highest number of Fell discoveries in Uruguay (Baeza and Femenías, 1999, Nami, 2013) . However, in its eastern part an interesting number of similar finds were made. Near CL, fishtails were found at Rocha department (Figure 4e, g; Figueira, 1892: figures 198-199; Bosch et al., 1980: figures 19, 21, 30; Nami, 2013: figure 24d ). Moreover, similar pieces were recorded from Merin Lagoon at Treinta Tres department (Bosch et al., 1980: figure 27) . In the northern border, in south Brazil points were reported from Santa Catarina and Rio Grande do Sul states (da Silva Lopes and Nami, 2011, Loponte et al., 2015) .
From the technological perspective, worth to mention that as a part of the bifacial thinning process, a common fact is the presence of flake-scars with different degree of regularity over passing the symmetry axis of a biface. Sometimes, they undercut previous scars from the opposite margin (Callahan, 1979: 10, Whittaker et al., 1988, Root, 1993: figure 43g-j) . However, as depicted in Figure 7, the edge-to-edge (EE) and/or overshot (O) percussion flaking in bifacial reduction is a conceptually different strategy to the usual thinning flake detaching; this is because it rapidly thin a worked piece by removing a few flakes that almost reach the opposite edge, or it is entirely eliminated (Inizan and Tixier, 1978, Bradley, 1982, Nami, 1988/1990: figure 53c, Stanford and Bradley, 2012) . In this sense, remarkably, two specimens from Rocha (Figure 4(c), Figure 4(g)) display the use of EE and/or O detachments, also identified in other pieces from Baygorria dam area (Figure 4(d)), Negro river basin; La Palomita, Yi river basin; and Buena Vista hill (Figure 4(f) and Figure 4(g)). In Uruguayan Fell point manufacture it was experimentally explained by Nami (2010a) , and furthermore, its use in archaeological artifacts (Nami, 2013, Nami and Castro, 2014) . Like the fluting, its employment was a minority. Additionally, in other parts of South America this particular method was recognized in the Ilaló region, Ecuador (Nami, 2014b) . It is important to recall that in North America EE and O percussion was a widespread Paleo-American flaking tactic (Stanford and Bradley, 2012) . Also in Central and northern South America EE and O flaking was identified in preforms and thinning flakes (Cooke and Sánchez, 2003; Pearson and Ream, 2005) . It is also clearly observed in finished products with expanded incurvate stems and concave bases from Ladyville, Belize (Hester et al., 1983: figure 2) and Turriabla, Costa Rica (Snarkis, 1979: figure 3b) which are comparable to examples from eastern USA. It is worth mentioning that the Uruguayan lanceolate variety with narrow blade and expanding stem resembles some fishtailed points from eastern North, Central and South America. Hence, due to morphological and technical similarities, I have suggested that South-American fishtails might have certain continuity with the fishtailed points from eastern North America (Nami, 2013) . In this regard, the new data presented here support this hypothesis; probably related with second colonization wave that colonized North America as suggested by Goebel and colleagues (2008) .
As seen above, Paleoindian remains from CL come from locales on fluvial courses. This fact is consistent with similar archaeological evidence in the southern cone (Nami, 2013) ; a circumstance that agrees with the hypothesis that fluvial environments were a significant factor in human continental colonization that, like in North America, was performed by a rapid dispersal (Anderson et al., 2013) .
Acknowledgements
I am indebted to: CONICET and UBA for support my investigations, NMNH (Smithsonian Institution) for his support as associated researcher, Museo Nacional de Antropología de Uruguay for having sponsored my archaeological research; A.Toscano and A. Florines, for their constant support and help; V. H. Gannello and I.
Figure 7. Schematic drawing showing the EE (a) and O (b) flaking tactic used to rapidly thin a bifacial piece.
Solimando from the MRCL for their valuable assistance in Melo. U. Meneghin kindly provided the Figure 2(a), Figures 4(a)-(c), Figure 4(e), Figure 4(f) and Figure 6(f). J. A special thanks to J. Rendo for allow me to study his collection, continuous data input, kindness and generosity. J. C. Whittaker provided useful observations, help and cooperation during the edition of this paper.