Hostname: page-component-586b7cd67f-t8hqh Total loading time: 0 Render date: 2024-11-26T05:53:34.213Z Has data issue: false hasContentIssue false
  • English
  • Français

Social Complexity and Food Systems at Altun Ha, Belize: The Isotopic Evidence

Published online by Cambridge University Press:  20 January 2017

Christine D. White ,
David M. Pendergast ,
Fred J. Longstaffe  and
Kimberley R. Law
Christine D. White
Affiliation:
Department of Anthropology, The University of Western Ontario, London, Ontario, Canada N6A 5C2
David M. Pendergast
Affiliation:
Royal Ontario Museum, Toronto, Ontario, Canada
Fred J. Longstaffe
Affiliation:
Department of Earth Sciences, The University of Western Ontario, London, Ontario, Canada N6A 5C2
Kimberley R. Law
Affiliation:
Department of Earth Sciences, The University of Western Ontario, London, Ontario, Canada N6A 5C2
Get access Rights & Permissions [Opens in a new window]

Abstract

This study reports stable carbon-isotope ratios for both bone collagen and apatite, and nitrogen-isotope ratios for bone collagen for 72 Maya skeletons from 9 zones representing contrasting status groups at Altun Ha, Belize. The sample spans the Preclassic to Postclassic periods, approximately 800 B. C. to after A. D. 950. Although Altun Ha has a maize-based (C-4) diet, it has a much stronger marine/reef component than any other Maya site studied so far. Two possible dedicatory burial groups are dietarily distinct. The source of protein appears to have been fairly stable throughout the site sequence, but a marked shift to reduced consumption of C4 foods seems to have occurred after the Early Classic period. A second similar decline probably occurred between the Late/Terminal Classic and the Postclassic periods. These apparent temporal trends may, however, be confounded by differences between zones. High status is marked by consumption of large quantities of C4 foods, possibly including C4-fed terrestrial animals. Males consumed more meat and C4 foods than did females. All δ-values and collagen-apatite spacings indicate that children were breastfed until at least the age of three or four.

Resumen

Resumen

En este estudio se presentan los resultados del análisis de la proporción entre isótopos de carbón estable tanto para colágeno de hueso como para apatita, además de isótopos de nitrógeno para colágeno de hueso, con base en el análisis de muestras correspondientes a 72 esqueletos humanos del sitio maya de Altun Ha, Belice, próximo a la costa. Las muestras datan del periodo Preclásico al Posclásico, aproximadamente desde 800 A. C. hasta tiempos posteriores a 950 D. C., además de que comparan individuos de nueve áreas excavadas que representan distintos grupos de diferentes niveles sociales. Al cotejar los datos de ambas fases del material óseo, orgánicas e inorgánicas, es posible determinar de manera general el consumo de alimentos contrastando el C-3 con el C-4, proporciones generales de macronutrientes, la fuente de proteína, y el grado de consumo de carnes en contraposición al consumo de vegetales. La dieta en Altun Ha demuestra distintos niveles de complejidad que a su vez reflejan la complejidad social de la sociedad maya. Mientras en Altun Ha se detecta una dieta basada en el maíz (C-4), común con sitios mayas de otras regiones, se identifica un componente marino y de arrecifes mucho más representado que en cualquier otro sitio maya hasta ahora estudiado. El consumo significativo de recursos marinos y de arrecife causa una apariencia artificial del énfasis en proteínas de esa procedencia, que caracteriza a poblaciones costeras en otros lugares del mundo. En el caso de dos muestras que se interpreta corresponden a sacrificios dedicatorios (Estructura C-13 y periodo Clásico Terminal en la Zona E), se observa una dieta distinta, pero para la Estructura C-13, esta distinción se puede confundir con diferencias temporales. Mientras el consumo de proteínas que se evidencia en los valores 15Ncol parece haber sido relativamente estable a lo largo de la secuencia del sitio (con la excepción de diferencias asociadas con la edad y el sexo de los individuos), al parecer hay cambio marcado hacia una reducción en el consumo de alimentos que contienen el C-14 parece que ocurre después del Clásico Temprano. Otra segunda disminución probablemente ocurrió entre el Clásico Tardío/Terminal y en el periodo Posclásico. Sin embargo, estas aparentes tendencias temporales pueden ser confundidas como diferencias entre las zonas en distintos periodos. Para las muestras de los individuos de estatus alto al parecer hay un alto grado de consumo de alimentos con C4, que también pueden haber incluido animales terrestres consumidores de C4. Hay una variabilidad dietética entre las elites de niveles inferiores, que además está por lo general basada en una jerarquía local. Los hombres consumían más comidas enriquecidas en 13C que las mujeres. Todos los valores de δ y espacios de colágena-apatita indican que los hijos eran amamantados por la madre hasta por lo menos la edad de tres o cuatro años.

Type
Articles
Information
Latin American Antiquity , Volume 12 , Issue 4 , December 2001 , pp. 371 - 393
Copyright
Copyright © Society for American Archaeology 2001

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

References Cited

Ambrose, Stanley. H. 1986 Stable Carbon and Nitrogen Isotope Analysis of Human and Animal Diet in Africa. Journal of Human Evolution 15:707731.Google Scholar
Ambrose, Stanley. H. 1990 Preparation and Characterization of Bone and Tooth Collagen for Stable Carbon and Nitrogen Isotope Analysis. Journal of Archaeological Science 17:431451.Google Scholar
Ambrose, Stanley. H. 1993 Isotopic Analysis of Palaeodiets: Methodological and Interpretive Considerations. In Investigations of Ancient Human Tissue: Chemical Analyses in Anthropology, edited by Mary K. Sandford, pp. 59130. Gordon and Breach Science, Amsterdam.Google Scholar
Ambrose, Stanley H., and DeNiro, Michael J. 1986 The Isotope Ecology of East African Mammals. Oecologia 69:395406.CrossRefGoogle ScholarPubMed
Ambrose, Stanley H., and Norr, Lynette 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 Prehistoric Human Bone: Archaeology at the Molecular Level, edited by Joseph Lambert and Gisela Grupe, pp. 137. Springer-Verlag. Berlin.Google Scholar
Arnold, Jeanne E., and Ford, Annabel 1980 An Statistical Examination of Settlement Patterns at. Tikal, Guatemala. American Antiquity 45:713726.CrossRefGoogle Scholar
Aufderheide, Arthur C, Tieszen, Larry L., Allison, Marvin J.. Wallgren, JoAnn, and Rapp, George Jr. 1988 Chemical Reconstruction of Components in Complex Diets: A Pilot Study. In Diet and Subsistence: Current Archaeological Perspectives, edited by Brenda E. Kennedy and Genevieve M. LeMoine, pp. 301306. Archaeology Association, University of Calgary, Calgary.Google Scholar
Becker, Marshall J. 1992 Burials as Caches; Caches as Burials: A New Interpretation of the Meaning of Ritual Deposits among the Classic Period Lowland Maya. In New Theories on the Ancient Maya, edited by E. C. Danien and Robert J. Sharer, pp. 185196. University Museum Monograph 77, University of Pennsylvania.Google Scholar
Brenner, Mark, Leyden, Barbara, and Binford, Michael W. 1990 Recent Sedimentary Histories of Shallow Lakes in the Guatemalan Savannas. Journal of Palaeolimnologv 4:239252.Google Scholar
Chase, Diane Z., and Chase, Arlen F. (editors) 1992 Mesoamerican Elites: An Archaeological Assessment. University of Oklahoma Press, Norman.Google Scholar
Chisholm, Brian S., Earle Nelson, D., Hobson, Keith A., Schwarcz, Henry P., and Knyf, Martin 1983 Carbon Isotope Measurement Techniques for Bone Collagen: Notes for the Archaeologist. Journal of Archaeological Science 10:335360.CrossRefGoogle Scholar
Cohen, Mark N., O'Connor, Kathleen, Danforth, Marie, Jacobi, Keith, and Armstrong, Carl 1994 Health and Death at Tipu. In In the Wake of Contact: Biological Responses to Conquest, edited by Clark S. Larsen and George Milner, pp. 121133. Wiley-Liss, New York.Google Scholar
Coplen, Tyler B. 1994 Reporting of Stable Hydrogen, Carbon and Oxygen Isotopic Abundances. Pure and Applied Chemistry 66:271276.Google Scholar
Counihan, Carole, and van Esterik, Penny (editors) 1997 Food and Culture. Routledge, New York.Google Scholar
Coyston, Shannon 1995 An Application of Carbon Isotope Analysis of Bone Apatite to the Study of Maya Diets and Subsistence at Pacbitun and Lamanai, Belize. M.A. thesis, Department of Anthropology, Trent University.Google Scholar
Coyston, Shannon, White, Christine D., and Schwarcz, Henry P. 1999 Dietary Carbonate Analysis of Bone and Enamel for Two Sites in Belize. In Reconstructing Ancient Maya Diet, edited by Christine D. White, pp. 199220. University of Utah Press, Salt Lake City.Google Scholar
Crane, Cathy J. 1986 Late Preclassic Maya Agriculture, Wild Plant Utilization and Land-use Practices. In Archaeology at Cerros. Belize, Central America, Vol. 1: An Interim Report, edited by David A. Freidel, pp. 147151. Southern Methodist University, Dallas.Google Scholar
Culbert, T. Patrick 1988 The Collapse of Classic Maya Civilization. In The Collapse of Ancient States and Civilizations, edited by Norman Yoffee and George L. Cowgill, pp. 69101. University of Arizona Press, Tucson.CrossRefGoogle Scholar
Danforth, Marie E. 1997 Childhood Health Patterns in the Late Classic Maya: Evidence from Enamel Microdefects. In Bones of the Ancestors: Recent Studies of Ancient Maya Skeletons, edited by Stephen Whittington and David Reed, pp. 127137. Smithsonian Institution Press, Washington, D.C. Google Scholar
DeLaurier, April 1997 An Analysis of Inter- and Intra-Site Mortuary Variability among Classic Lowland Maya Sites. Paper presented at the Annual Meeting of the Canadian Association for Physical Anthropology, London, Ontario.Google Scholar
Delwiche, Constant C, and Steyn, Pieter L. 1970 Nitrogen Isotope Fractionation in Soils and Microbial Reactions. Environmental Science and Technology 4:929935.Google Scholar
DeNiro, Michael. J. 1985 Post-Mortem Preservation and Alteration of “In Vivo” Bone Collagen Isotope Ratios in Relation to Paleodietary Reconstruction. Nature 317:806809.Google Scholar
DeNiro, Michael. J. 1987 Stable Isotopy and Archaeology. American Scientist 75:182191.Google Scholar
DeNiro, Michael J., and Epstein, Samuel 1977 Mechanisms of Carbon Isotope Fractionation Associated with Lipid Synthesis. Science 197:261263.CrossRefGoogle ScholarPubMed
DeNiro, Michael J., and Epstein, Samuel 1978 Influence of Diet on the Distribution of Nitrogen Isotopes in Animals. Geochimica et Cosmochimica Acta 42:495506.Google Scholar
DeNiro, Michael J., and Epstein, Samuel 1981 Influence of Diet on the Distribution of Nitrogen Isotopes in Animals. Geochimica et Cosmochimica Acta 45:341351.Google Scholar
DeNiro, Michael J., and Weiner, Stephen 1988 Chemical, Enzymatic and Spectroscopic Characterization of “Collagen” and Other Organic Fractions from Prehistoric Bones. Geochimica et Cosmochimica Acta 52:21972206.Google Scholar
Ericson, Jonathan E., West, Michael, Sullivan, Charles H., and Krueger, Harold W. 1989 The Development of Maize Agriculture in the Viru Valley, Peru. In The Chemistry of Prehistoric Bone, edited by T. Douglas Price, pp. 680704. Cambridge University Press, Cambridge.Google Scholar
Farb, Peter, and Armelagos, George J. 1980 Consuming Passions: The Anthropology of Eating. Houghton Mifflin, Boston.Google Scholar
Flannery, Kent V. (editor) 1982 Maya Subsistence: Studies in Memory of Dennis Puleston. Academic Press, New York.Google Scholar
Fogel, Marilyn L., Tuross, Noreen, and Owsley, Douglas 1989 Nitrogen Isotope Tracers of Human Lactation in Modern and Archaeological Populations. Annual Report of the Director, Geophysical Laboratory, Carnegie Institution of Washington, 1988–1989, pp. 111116.Google Scholar
Folan, William J., Kintz, Ellen R., Fletcher, Laraine A., and Hyde, B. H. 1982 An Examination of Settlement Patterns at Coba, Quintana Roo, Mexico and Tikal, Guatemala: A Reply to Arnold and Ford. American Antiquity 47:430436.CrossRefGoogle Scholar
Friedli, H., Lotscher, H., Oescheger, H., Siegenthaler, U., and Stauffer, B. 1986 Ice Core Record of the 13C/12C Ratio of Atmospheric CO2, in the Past Two Centuries. Nature 324:237238.Google Scholar
Gerry, John P., and Krueger, Harold W. 1997 Regional Diversity in Classic Maya Diets. In Bones of the Ancestors: Recent Studies of Ancient Maya Skeletons, edited by Stephen Whittington and David Reed, pp. 196207. Smithsonian Institution Press, Washington, D.C. Google Scholar
Goody, Jack 1982 Cooking, Cuisine, and Class: A Study in Comparative Sociology. Cambridge University Press, Cambridge.Google Scholar
Gumerman, George IV 1997 Food and Complex Societies. Journal of Archaeological Method and Theory 4:105139.Google Scholar
Harris, Marvin, and Ross, Eric B. (editors) 1987 Food and Evolution: Toward a Theory of Food Habits. Temple University Press, Philadelphia.Google Scholar
Heaton, Timothy H. E., Vogel, J. C., Chevallarie, Gertrude, and Collet, Gill 1986 Climatic Influence on the Isotopic Composition of Bone Nitrogen. Nature 322:822823.Google Scholar
Hellmuth, Nicholas M. 1977 Cholti-Lacandon (Chiapas) and Peten-Itza Agriculture. In Social Process in Maya Prehistory, edited by Norman Hammond, pp. 421428. Academic Press, New York.Google Scholar
Hodell, David A., Curtis, Jason H., and Brenner, Mark 1995 Possible Role of Climate in the Collapse of Classic Maya Civilization. Nature 375:391394.Google Scholar
Hooton, Ernest A. 1940 Skeletons from the Cenote of Sacrifice at Chichen Itza. In The Maya and Their Neighbors, edited by Clarence Hay, Ralph L. Linton, Samuel K. Lothrgp, Harry L. Shapiro, and George C. Vaillant, pp. 272280. Appleton-Century, New York.Google Scholar
Katzenberg, M. Anne, and Lovell, Nancy C. 1999 Stable Isotope Variation in Pathological Bone. International Journal of Osteoarchaeology 9:316324.Google Scholar
Katzenberg, M. Anne, Ann Herring, D., and Saunders, Shelley R. 1996 Weaning and Infant Mortality: Evaluating the Skeletal Evidence. Yearbook of Physical Anthropology 39:177199.Google Scholar
Keegan, William E, and DeNiro, Michael J. 1988 Stable Carbon- and Nitrogen-Isotope Ratios of Collagen Used to Study Coral-Reef and Terrestrial Components of Prehistoric Bahamian Diet. American Antiquity 53:320336.Google Scholar
Keeling, Charles D., Mook, Willem G., and Tans, Pieter P. 1979 Recent Trends in the 13C/12C Ratio of Atmospheric Carbon Dioxide. Nature 277:121123.Google Scholar
Kendall, Carol, and Grim, Elizabeth 1990 Combustion Tube Method for Measurement of Nitrogen Isotope Ratios Using Calcium Oxide for Total Removal of Carbon Dioxide and Water. Analytical Chemistry 62:526529.CrossRefGoogle Scholar
Krueger, Harold W., and Sullivan, Charles H. 1984 Models for Carbon Isotope Fractionation between Diet and Bone. In Stable Isotopes in Nutrition, edited by Judith R. Turnland and Phyliss E. Johnson, pp. 205222. American Chemical Society Symposium Series 258, American Chemical Society, Washington, D.C. Google Scholar
Lee-Thorp, Julia, and van der Merwe, Nikolaas J. 1991 Aspects of the Chemistry of Modern and Fossil Biological Apatites. Journal of Archaeological Science 18:343354.Google Scholar
Lee-Thorp, Julia, Sealy, Judy C., and van der Merwe, Nikolaas J. 1989 Stable Carbon Isotope Ratio Differences between Bone Collagen and Bone Apatite, and Their Relationship to Diet. Journal of Archaeological Science 16:585599.Google Scholar
Longin, R. 1971 New Method of Collagen Extraction for Radiocarbon Dating. Nature 230:241242.CrossRefGoogle ScholarPubMed
Marcus, Joyce 1982 The Plant World of the Sixteenth- and Seventeenth-Century Lowland Maya. In Maya Subsistence: Studies in Honor of Dennis Puleston, edited by Kent V. Flannery, pp. 239273. Academic Press, New York.Google Scholar
Marino, Bruno D., and McElroy, Michael B. 1991 Isotopic Composition of Atmospheric O2, Inferred from Carbon in C4 Plant Cellulose. Nature 349:127131.Google Scholar
Miksicek, Charles H. 1983 Macrofloral Remains of the Pulltrouser Area: Settlements and Fields. In Pulltrouser Swamp: Ancient Maya Habitat, Agriculture, and Settlement in Northern Belize, edited by B. L. Turner II and Peter D. Harrison, pp. 94104. University of Texas, Austin.Google Scholar
Miksicek, Charles H. 1991 The Ecology and Economy of Cuello. In Cuello: An Early Maya Community in Belize, edited by Norman Hammond, pp. 7084. Harvard University Press, Cambridge.Google Scholar
Norr, Lynette 1991 Nutritional Consequences of Prehistoric Subsistence Strategies in Lower Central America. PhD. dissertation, University of Illinois at Urbana-Champaign. University Micro-films, Ann Arbor.Google Scholar
O'Leary, Marion 1988 Carbon Isotopes in Photosynthesis. Bioscience 38:328336.Google Scholar
Peebles, Christopher S., and Kus, Susan M. 1977 Some Archaeological Correlates of Ranked Societies. American Antiquity 44:421448.Google Scholar
Pendergast, David M. 1979 Excavations at Altun Ha, Belize, 1964–1970, Vol. 1. Royal Ontario Museum, Toronto.Google Scholar
Pendergast, David M. 1982 Excavations at Altun Ha, Belize, 1964–1970, Vol. 2. Royal Ontario Museum, Toronto.Google Scholar
Pendergast, David M. 1990 Excavations at Altun Ha, Belize, 1964–1970, Vol. 3. Royal Ontario Museum, Toronto.Google Scholar
Pendergast, David M. 1992 Noblesse Oblige: The Elites of Altun Ha and Lamanai, Belize. In Mesoamerican Elites: An Archaeological Assessment, edited by Diane Z. Chase and Arlen F. Chase, pp. 6179. University of Oklahoma Press, Norman.Google Scholar
Pohl, Mary 1990 Ancient Maya Wetland Agriculture: Excavations on Albion Island, Northern Belize. Westview Press, Boulder.Google Scholar
Reed, David M. 1994 Ancient Maya Diet at Copén, Honduras, as Determined through the Analysis of Stable Carbon and Nitrogen Isotopes. In Paleonutrition: The Diet and Health of Prehistoric Americans, edited by Kristin D. Sobolik, pp. 210221. Occasional Papers Series, Center for Archaeological Investigations, Southern Illinois University, Carbondale.Google Scholar
Reed, David M. 1999 Cuisine from Hun-Nal-Ye. In Reconstructing Ancient Maya Diet, edited by Christine White, pp. 183196. University of Utah Press, Salt Lake City.Google Scholar
Roksandic, Zarko, Minigawa, Masao, and Akazawa, T. 1988 Comparative Analysis of Dietary Habits between Jomon and Ainu Hunter/Gatherers from Stable Carbon Isotopes of Human Bone. Journal of the Anthropological Society of Nippon 96:391404.Google Scholar
Rue, D. 1987 Early Agriculture and Early Postclassic Maya Occupation in Western Honduras. Nature 326:285286.Google Scholar
Santley, Robert S., Killion, Thomas W., and Lycett, Mark T. 1986 On the Maya Collapse. Journal of Anthropological Research 42:123159.Google Scholar
Saul, Frank P. 1972 The Human Skeletal Remains of Altar de Sacrificios: An Osteobiographic Analysis. Papers of the Peabody Museum of Archaeology and Ethnology, Vol. 63, No. 2. Harvard University Press, Cambridge.Google Scholar
Saul, Frank P. 1975 Appendix 8 - Human Remains from Lubaantun. In Lubaantun, a Classic Maya Realm, edited by Norman Hammond, pp. 389410. Peabody Museum of Archaeology and Ethnology Monograph No. 2. Harvard University, Cambridge.Google Scholar
Saul, Frank P., and Saul, Julie M. 1991 The Preclassic Population of Cuello. In Cuello: An Early Maya Community in Belize, edited by Norman Hammond, pp. 134158. Cambridge University Press, Cambridge.Google Scholar
Scarborough, Vernon L. 1991 The Settlement System in a Late Preclassic Maya Community, Vol. 3 of Archaeology at Cerros, Belize. Series edited by David Freidel. Southern Methodist University Press, Dallas.Google Scholar
Schoeninger, Margaret J. 1985 Trophic Level Effects on 15N/15N and 13C/12C Ratios in Bone Collagen and Strontium Levels in Bone Mineral. Journal of Human Evolution 14:515525.Google Scholar
Schoeninger, Margaret J., and DeNiro, Michael J. 1984 Nitrogen and Carbon Isotope Composition of Bone Collagen from Marine and Terrestrial Animals. Geochimica et Cosmochimica Acta 48:625639.Google Scholar
Schwarcz, Henry P. 2000 Some Biochemical Aspects of Carbon Isotopic Paleodiet Studies. In Biogeochemical Approaches to Paleodietary Analysis, edited by Stanley Ambrose and M. Anne Katzenberg, pp. 189210, Plenum Press, New York.Google Scholar
Schwarcz, Henry P., and Schoeninger, Margaret J. 1991 Stable Isotope Analysis in Human Nutritional Ecology. Yearbook of Physical Anthropology 34:283321.Google Scholar
Sealy, Judy, and van der Merwe, Nikolaas J. 1986 Isotope Assessment of the Seasonal Mobility Hypothesis in the Southwestern Cape, South Africa. Current Anthropology 27:135150.Google Scholar
Sealy, Judy, van der Merwe, Nikolaas J., Lee-Thorp, Julia J., and Lanham, John L. 1987 Nitrogen Isotope Ecology in Southern Africa: Implications for Environmental and Dietary Tracing. Geochimica et Cosmochimica Acta 51:27072717.Google Scholar
Shemesh, Aldo 1990 Crystallinity and Diagenesis of Sedimentary Apatites. Geochimica et Cosmochimica Acta 54:24332438.Google Scholar
Smith, Bruce N., and Epstein, Samuel 1971 Two categories of 13C/12C ratios for higher plants. Plant Physiology 47:380384.Google Scholar
Song, Rhan-Ju 1997 Developmental Defects of Enamel in the Maya of Altun Ha, Belize: Implications for Ancient Maya Childhood Health. Unpublished M. A. thesis, Department of Anthropology, Trent University.Google Scholar
Storey, Rebecca 1992 The Children of Copan: Issues in Paleopathology and Palaeodemography. Ancient Mesoamerica 3:161167.Google Scholar
Stuart-Williams, Hilary Le Q., Schwarcz, Henry P., White, Christine D., and Spence, Michael W. 1996 The Isotopic Composition and Diagenesis of Human Bone from Teotihuacan and Oaxaca, Mexico. Palaeogeography, Palaeoclimatology, Palaeoecology 126:114.Google Scholar
Termine, John D., and Posner, Aaron S. 1966 Infrared Analysis of Rat Bone: Dependency of Amorphous and Crystalline Mineral Fractions. Science 153:15231525.CrossRefGoogle ScholarPubMed
Tieszen, Larry L., Boutton, Thomas W., Tesdahl, K.G., and Slade, Norman A. 1983 Fractionation and Turnover of Stable Carbon Isotopes in Animal Tissues: Implications for 13C analysis of Diet. Oecologia 57:3237.Google Scholar
Tieszen, Larry L., and Boutton, Thomas W. 1988 Stable Carbon Isotopes in Terrestrial Ecosystem Research. In Stable Isotopes in Ecological Research, edited by P.W. Rundel, pp. 167194. Springer-Verlag, Berlin.Google Scholar
Tieszen, Larry L., and Fagre, Tim 1993 Effect of Diet Quality and Composition on the Isotopic Composition of Respiratory CO2 Bone Collagen, Bioapatite, and Soft Tissues. In Prehistoric Human Bone: Archaeology at the Molecular Level, edited by Joseph Lambert and GiselaGrupe, pp. 121155. Springer-Verlag, Berlin.Google Scholar
Tozzer, Alfred M. 1941 Landa's Relación de las cosas de Yucatán. Papers of the Peabody Museum of Archaeology and Ethnology, Vol. 18. Harvard University Press, Cambridge.Google Scholar
Turner, B. L. II, and Harrison, Peter (editors) 1983 Pulltrouser Swamp: Ancient Maya Habitat, Agriculture and Settlement in Northern Belize. University of Texas Press, Austin.Google Scholar
Tykot, Robert H., van der Merwe, Nikolaas J., and Hammond, Norman 1996 Stable Isotope Analysis of Bone Collagen, Bone Apatite, and Tooth Enamel in the Reconstruction of Human Diet: A Case Study for Cuello, Belize. In Archaeological Chemistry V, edited by Mary V. Orna, pp. 355365. American Chemical Society, Washington, D.C. Google Scholar
van der Merwe, Nikolaas J., and Vogel, Johannes C. 1978 13C Content of Human Collagen as a Measure of Prehistoric Diet in Woodland North America. Nature 276:815816.Google Scholar
Webster, David, Sanders, William T., and van Rossum, Peter 1992 A Simulation of Copán Population History and Its Implications. Ancient Mesoamerica 3:185197.Google Scholar
Weiner, Stephen, and Yosef, Ofar Bar 1990 States of Preservation of Bones from Prehistoric Sites in the Near East: A Survey. Journal of Archaeological Science 17:187196.Google Scholar
Welsh, W M., Bruce 1988 An Analysis of Classic Lowland Maya Burials. British Archaeological Reports, International Series 409. BAR, Oxford.Google Scholar
White, Christine D. 1986 Palaeodiet and Nutrition of the Ancient Maya at Lamanai Belize: A Study of Trace Elements, Stable Isotopes, Nutritional and Dental Pathologies. M.A. thesis, Department of Anthropology, Trent University.Google Scholar
White, Christine D. 1994 Dietary Dental Pathology and Cultural Change in the Maya. In Strength in Diversity, edited by Lesliel K. W. Chan and Ann Herring, pp. 279302. Canadian Scholar’s Press, Toronto.Google Scholar
White, Christine D. 1997 Ancient Diet at Lamanai and Pacbitun: Implications for the Ecological Model of Collapse. In Bones of the Ancestors: Recent Studies of Ancient Maya Skeletons, edited by Stephen Whittington and David Reed, pp. 171180. Smithsonian Institution Press, Washington, D.C. Google Scholar
White, Christine D. (editor) 1999 Reconstructing Ancient Maya Diet. University of Utah Press, Salt Lake City.Google Scholar
White, Christine D., and Armelagos, George J. 1997 Osteopenia and Stable Isotope Ratios in Bone Collagen of Nubian Female Mummies. American Journal of Physical Anthropology 93:165187.Google Scholar
White, Christine D., Healy, Paul F., and Schwarcz, Henry P. 1993 Intensive Agriculture, Social Status and Maya Diet at Pacbitun, Belize. Journal of Anthropological Research 49:347375.Google Scholar
White, Christine D., Longstaffe, Fred J., and Song, Rhan-Ju 1996 Preclassic Maya Diet at Cahal Pech: The Isotopic Evidence. Paper presented at the Annual Meeting of the Society for American Archaeology, New Orleans.Google Scholar
White, Christine D., Wright, Lori E., and Pendergast, David M. 1994 Biological Disruption in the Early Colonial Period at Lamanai. In In the Wake of Contact: Biological Responses to Conquest, edited by Clark S. Larsen and George Milner, pp. 135145. Wiley-Liss, New York.Google Scholar
White, Christine D., and Schwarcz, Henry P. 1989 Ancient Maya Biet: As Inferred from Isotopic and Elemental Analysis of Human Bone. Journal of Archaeological Science 16:451474.Google Scholar
Whittington, Stephen L. 1989 Characteristics of Demography and Disease in Low Status Maya from Classic Period Copán, Honduras. Unpublished Ph.D. dissertation, Department of Anthropology, Pennsylvania State University, University Park.Google Scholar
Whittington, Stephen L., and Reed, David M. 1994 Los esqueletos de Iximché. In VII Simpósio de lnvestigaciones Arqueológicas en Guatemala, 1993, edited by J. P. Laporte and H. L. Escobedo, pp. 2328. Ministerio de Cultura y Deportes, Instituto de Antropología e Historia, Asociación Tikal, Guatemala.Google Scholar
Willey, Gordon R., and Shimkin, D. B. 1973 The Maya Collapse: A Summary View. In The Classic Maya Collapse, edited by T. Patrick Culbert, pp. 457502. University of New Mexico Press, Albuquerque.Google Scholar
Wright, Lori E. 1994 Sacrifice of the Earth? Diet, Health, and Inequality in the Pasión Maya. Unpublished Ph.D. dissertation, Department of Anthropology, University of Chicago.Google Scholar
Wright, Lori E., and Schwarcz, Henry P. 1996 Infrared and Isotopic Evidence for Diagenesis of Bone Apatite at Dos Pilas, Guatemala: Paleodietary Implications. Journal of Archaeological Science 23:933944.Google Scholar
Wright, Lori E., and White, Christine D. 1996 Human Biology in the Classic Maya Collapse: Evidence from Paleopathology and Paleodiet. Journal of World Prehistory 10:147198.Google Scholar