64. Ambrose, S. H. (1993). Isotopic analysis of paleodiets: Methodological and interpretive considerations. In Sandford, M. K.
Yüklə 36,29 Kb.
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64. Ambrose, S. H. (1993). Isotopic analysis of paleodiets: Methodological and interpretive considerations. In Sandford, M. K. (ed.), Investigations of Ancient Human Tissue: Chemical Analyses in Anthropology, Gordon and Breach Science, Langhorne, pp. 59-130. 5. Ambrose, S. H., and Katzenberg, M. A. (eds.) (1998). Close to the Bone: Biogeochemicat Approaches to Paleodietary Analysis in Archaeology, Advances in Archaeological and Museum Science, Plenum Press, New York (in preparation). 62. Ambrose, S. H., 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, J. B., and Grupe, G. (eds.), Prehistoric Human Bone: Archaeology at the Molecular Level, Springer-Verlag, Berlin, pp. 1-37. 10. Aufderheide, A. C. (1989). Chemical analysis of skeletal remains. In Iscan, M. Y., and Kennedy, K. A. R. (eds.), Reconstruction of Life from the Skeleton, Alan R. Liss, New York, pp. 237-260. 33. Blake, M., Chisholm, B. S., Clark, J. E., Voorhies, B., and Love, M. W. (1992). Prehistoric subsistence in the Soconusco region. Current Anthropology 33: 83-94. 81. Blakely, R. L. (1989). Bone strontium in pregnant and lactating females from archaeological samples. American Journal of Physical Anthropology 811: 173-186. 49. Bocherens, H., Fizet, M., Mariotti, A., Olive, C., Bellon, G., and Billiou, D. (1991a). Application de la biogeochimie isotopique (13C,15N) a la drtermination du rrgime alimentaire des populations humaines et animales durant les preriodes antique et mrdirvale. Arch Sci. Gen~ve 44: 329-340. 50. Bocherens, H., Fizet, M., Mariotti, A., Lange-Badre, B., Vandermeersch, B., Borel, J. P., and Bellon, G. (1991b). Isotopic biogeochemistry (13C,15N) of fossil vertebrate collagen: Application to the study of a past food web including Neandertal man. Journal of Human Evolution 20: 481-492. 66. Bourque, B. J., and Krneger, H. W. (1994). Dietary reconstruction from human bone isotopes for five coastal New England populations. In Sobolik, K. D. (ed.), Paleonutrition: The Diet and Health of Prehistoric Americans, Center for Archaeological Investigations, Southern Illinois University, Carbondale, pp. 195-209. 17. Boutton, T. W., Lynott, M. J., and Bumsted, P. M. (1991). Stable carbon isotopes and the study of prehistoric human diet. Critical Reviews in Food Science and Nutrition 30: 373-385. 18. Buikstra, J. E., and Milner, G. R. (1991). Isotopic and archaeological interpretations of diet in the central Mississippi valley. Journal of Archaeological Science 18: 319-329. 12. Buikstra, J. E., Frankenberg, S., Lambert, J. B., and Xue, L. (1989). Multiple elements: Multiple expectations. In Price, T. D. (ed.), The Chemistry of Prehistoric Human Bone, Cambridge University Press, Cambridge, pp. 155-210. 30. Burger, R. L., and van der Merwe, N. J. (1990). Maize and the origin of highland Chavin civilization: An isotopic perspective. American Anthropologist 92: 85-95. 78. Burton, J. H., and Wright, L. E. (1995). Nonlinearity in the relationship between bone Sr/Ca and diet: Paleodietary implications. American Journal of Physical Anthropology 96: 273-282. 26. Decker, K. W., and Tieszen, L. L. (1989). Isotopic reconstruction of Mesa Verde diet from Basketmaer III to Pueblo III. Kiva 55: 33-47. 54. DeNiro, M. J., and Epstein, S. (1978). Carbon isotopic evidence for different feeding patterns in two Hyrax species occupying the same habitat. Science 201: 906-908. 73. Edward, J. B., and Benfer, R. A. (1993). The effects of diagenesis on the Paloma skeletal material. In Sandford, M. K. (ed.), Investigations of Ancient Human Tissue: Chemical Analyses in Anthropology, Gordon and Breach Science, Langhorne, PA, pp. 183-268. 31. Ericson, J. E. (1989). Some problems and potentials of strontium isotope analysis for human and animal ecology. In Rundel, P. W., Ehteringer, J. R., and Nagy, tC A. (eds.), Stable Isotopes in Ecological Research, Ecological Studies 68, Springer-Verlag, New York, pp. 252-259. 16. Ezzo, J. A. (1994a). Putting the "chemistry" back into archaeological bone chemistry analysis: Modeling potential paleodietary indicators. Journal of Anthropological Archaeology 13: 1-34. 82. Ezzo, J. A. (1994b). Zinc as a paleodietary indicator: An issue of theoretical validity in bone-chemistry analysis. American Antiquity 59: 606-621. 23. Goodman, A. H., Lallo, J., Armelagos, G. J., and Rose, J. C. (1984). Health changes at Dickson Mounds, Illinois (A.D. 950- 1300). In Cohen, M. N., and Armelagos, G. J. (eds.), Paleopathotogy at the Origins of Agriculture, Academic Press, Orlando, FL, pp. 27t-305. 72. Grupe, G., and Piepenbrink, H. (1989). Impact of microbial activity on trace element concentrations in excavated bones. Applied Geochemistry 4: 293-298. 82. Hancock, R. G. V., Grynpas, M. D., and Pritzker, K. P. H. (1989). The abuse of bone analyses for archaeological dietary studies. Archaeometry 31: 169-t79. 34. Hayden, B., Chisholm, B., and Schwarcz, H. P. (1987). Fishing and foraging: Marine resources in the Upper Paleolithic of France. In Softer, O. (ed.), The Pleistocene Old World: Regional Perspectives, Plenum Press, New York, pp. 279-291. 69. Hedges, R. E. M., and Millard, A. R. (1995). Bones and groundwater: Towards the modelling of diagenetic processes. Journal of Archaeological Science 22: 155-164. 7. Katzenberg, M. A. (1992). Advances in stable isotope analysis of prehistoric bones. In Saunders, S. R., and Katzenberg, M. A. (eds.), The Skeletal Biology of Past Peoples: Research Methods, John Wiley and Sons, New York, pp. 105-120. 27. Katzenberg, M. A., and Kelley, J. H. (1991). Stable isotope analysis of prehistoric bone from the Sierra Blanca region of New Mexico. Beckett, P. H. (ed.), Mogollon F: Proceedings of the 1988 Mogollon Conference, Las Cruces, New Mexico, October 1988, COAS Publishing and Research, pp. 207-219. 45. Katzenberg, M. A., and Krouse, H. R. (1989). Application of stable isotopes in human tissues to problems in identification. Canadian Society of Forensic Science Journal 22: 7-19. 19. Katzenberg, M. A., and Pfeiffer, S. (1995). Nitrogen isotope evidence for weaning age in a nineteenth century Canadian skeletal sample. In Grauer, A. L. (ed.), Bodies of Evidence, John Wiley and Sons, Inc., New York, pp. 221-235. 48. Katzenberg, M. A., and Weber, A. (1996). Stable isotope ecology and Neolithic paleodiet in the Lake Baikal area. Paper presented at the 61st Annual Meeting of the Society for American Archaeology, New Orleans, Apr. 10-14. 6. Keegan, W. F. (1989). Stable isotope analysis of prehistoric diet. In Iscan, M. Y., and Kennedy, K.A.R. (eds.), Reconstruction of Life from the Skeleton, Alan R. Liss, New York, pp. 223-236. 35. Keegan, W. F., and DeNiro, M. J. (1988). Stable carbon-and nitrogen-isotope ratios of bone collagen used to study coral-reef and terrestrial components of prehistoric Bahamian diet. American Antiquity 53: 320-336. 20. Koch, P. L., Behrensmeyer, A. K., Tuross, N., and FogeI, M. L. (1990). Isotopic fidelity during bone weathering and burial. Carnegie Institution, Annual Report of the Director of the Geophysical Laboratory, 1989-1990, pp. 105-110. 36. Koike, H., and Chisholm, B. (1991). Paleodiet of hunter-gatherers in Japan estimated by 13C-15N and lipid analyses. Quaternary Research 30: 231-238. 56. Krueger, H. W. (1991). Exchange of carbon with biological apatite. Journal of Archaeological Science 18: 355-361. 61. Krueger, H. W., and Sullivan, C. H. (1984). Models for carbon isotope fractionation between diet and bone. Turnlund, J. E. and Johnson, P. E. (eds.), Stable Isotopes in Nutrition, American Chemical Society Symposium Series, Vol. 258, pp. 205-222. 47. Lam, Y. M. (1994). Isotopic evidence for change in dietary patterns during the Baikal Neolithic. Current Anthropology 35: 185-190. 2. Lambert, J. B., and Grupe, G. (eds.) (1993). Prehistoric Human Bone: Archaeology at the Molecular Leve~ Springer-Verlag, Berlin. 79. Lambert J. B., and Weydert-Homeyer, J. M. (1993a). The fundamental relationship between ancient diet and the inorganic constituents of bone as derived from feeding experiments. Archaeometry 35: 279-294. 80. Lambert, J. B., and Weydert-Homeyer, J. M. (1993b). Dietary inferences from element analysis of bone. In Lambert, J. B., and Grupe, G. (eds.), Prehistoric Human Bone: Archaeology at the Molecular Level, Springer-Verlag, Berlin, pp. 217-228. 24. Larsen, C. S., Schoeninger, M. J., van der Merwe, N. J., Moore, K. M., and Lee-Thorp, J. A. (1992). Carbon and nitrogen stable isotopic signatures of human dietary change in the Georgia Bight. American Journal of Physical Anthropology 89: 197-214. 60. Lee-Thorp, J. A. (1989). Stable Carbon Isotopes in Deep Time: The Diets of Fossil Fauna and Hominids, unpublished doctoral dissertation, Department of Archaeology, University of Cape Town, Cape Town. 67. Lee-Thorp, J. A., and van der Merwe, N. J. (1987). Carbon isotope analysis of fossil bone apatite. South African Journal of Science 83: 712-715. 59. Lee-Thorpe, J. A., and van der Merwe, N. J. (1991). Aspects of the chemistry of modern and fossil biological apatites. Journal of Archaeological Science 18: 343-354. 65. Lee-Thorp, J. A., Scaly, J, C., and van der Merwe, N. J. (1989a). Stable carbon isotope ratio differences between bone collagen and bone apatite, and their relationship to diet. Journal of Archaeological Science 16: 585-599. 68. Lee-Thorp, J. A., van der Merwe, N. J., and Brain, C. IC (1989b). Isotopic evidence for dietary differences between two extinct baboon species from Swartkrans, South Africa. Journal of Human Evolution 18: 183-190. 25. Little, E. A., and Schoeninger, M. J. (1995). The Late Woodland diet on Nantucket Island and the problem of maize in coastal New England. American Antiquity 60: 351-368. 37. Lubell, D., Jackes, M., Schwarcz, H., Knyf, M., and Meiklejohn, C. (1994). The Mesolithic-Neolithic transition in Portugal: Isotopic and dental evidence of diet. Journal of Archaeological Science 21: 201-216. 28. Matson, R. G., and Chisholm, B. (1991). Basketmaker II subsistence: Carbon isotopes and other dietary indicators from Cedar Mesa, Utah. American Antiquity 56: 444-459. 46. Murray, M. L., and Schoeninger, M. J. (1988). Diet, status, and complex social structure in Iron Age Central Europe: Some contributions of bone chemistry. In Gibson, B., and Geselowitz, M. (eds.), Tribe and Polity in Late Prehistoric Europe, Plenum Press, New York, pp. 155-176. 75. Nelson, B. K., DeNiro, M. J., Schoeninger, M. J., DePaolo, D. J., and Hare, P. E. (1986). Effects of diagenesis on strontium, carbon, nitrogen and oxygen concentration and isotopic composition of bone. Geochimica et Cosmochimica Acta 50: 1941-1949. 38. Norr, L. C. (1991). Nutritional Consequences of Prehistoric Subsistence Strategies in Lower Central America, unpublished Ph.D. dissertation, Department of Anthropology, University of Illinois at Urbana-Champaign, Urbana. 54. Parkington, J. E. (1972). Seasonal mobility in the Late Stone Age.African Studies 1: 223-243. 55. Parkington, J. E. (1986). On "Isotope assessment and the seasonal mobility hypothesis in the Southwestern Cape of South Africa. Current Anthropology 27: 145-146. 56. Parkington, J. E. (1987). On stable carbon isotopes and dietary reconstruction. Current Anthropology 28: 91-95. 57. Parkington, J. E. (1991). Approaches to dietary reconstruction in the Western Cape: Are you what you have eaten? Journal of Archaeological Science 18: 331-342. 9. Pate, F. D. (1994). Bone chemistry and paleodiet. Journal of Archaeological Method and Theory 1: 161-209. 3. Price, T. D. (ed.) (1989a). The Chemistry of Prehistoric Bone, Cambridge University Press, Cambridge. 11. Price, T. D. (1989b). Multi-element studies of diagenesis in prehistoric bone. In Price, T. D. (ed.), The Chemistry of Prehistoric Human Bone, Cambridge University Press, Cambridge, pp. 126-154. 15. Radosevich, S. C. (1993). The six deadly sins of trace element analysis: A case of wishful thinking in science. In Sandford, M. K. (ed.), Investigations of Ancient Human Tissue: Chemical Analyses in Anthropology, Gordon and Breach Science, Langhorne, pp. 269-332. 68. Robinson, J. T. (1954). Prehominid dentition and hominid evolution. Evolution 8: 324-334. 13. Sandford, M. K. (1992). A reconsideration of trace element analysis in prehistoric bone. In Saunders, S. R., and Katzenberg, M. A. (eds.), Skeletal Biology of Past Peoples: Research Methods, John Wiley and Sons, New York, pp. 79-104. 14. Sandford, M. K. (t993). Understanding the biogenic-diagenetic continuum: Interpreting elemental concentrations of archaeological bone. In Sandford, M. K. (ed.), Investigations of Ancient Human Tissue: Chemical Analyses in Anthropology, Gordon and Breach Science, Langhorne, pp. 3-57. 57. Schoeninger, M. J., and DeNiro, M. J. (1982). Carbon isotope ratios of apatite from fossil bone cannot be used to reconstruct diets of animals. Nature 297: 577-578. 58. Schoeninger, M. J., and DeNiro, M. J. (1983). Reply to: Carbon isotope ratios of bone apatite and animal diet reconstruction. Nature 301: 177-178. 21. Schurr, M. R. (1992). Isotopic and mortuary variability in a Middle Mississippian population. American Antiquity 57: 300-320. 22. Schurr, M. R., and Redmond, B. G. (1991). Stable isotope analysis of incipient maize horticulturists from the Gard Island 2 site. Midcontinental Journal of Archaeology 16: 69-84. 8. Schwarcz, H. P., and Schoeninger, M. J. (1991). Stable isotope analyses in human nutritional ecology. Yearbook of Physical Anthropology 34: 283-322. 39. Sealy, J. C. (1986). Stable Carbon Isotopes and Prehistoric Diets in the Southwestern Cape Province, South Africa, BAR International Series 293, Oxford. 40. Sealy, J. C., and Sillen, A. (1988). Sr and Sr/Ca in marine and terrestrial foodwebs in the Southwestern Cape, South Africa. Journal of Archaeological Science 15: 425-438. 52. Sealy, J. C., and van der Merwe, J. J. (1985). Isotope assessment of Holocene human diets in the South-western Cape, South Africa. Nature 315: 138-I40. 51. Sealy, J. C., and van der Merwe, N. J. (1986). Isotope assessment and seasonal mobility in the Southwestern Cape of South Africa. Current Anthropology 27: 135-150. 53. Sealy, J. C., and van der Merwe, N. J. (1988). Social, spatial and chronological patterning in marine food use as determined by 13C measurements of Holocene human skeletons from the South-western Cape, South Africa. World Archaeology 20: 87-102. 76. Sillen, A. (1986). Biogenic and diagenetic Sr/Ca in Plio-Pleistocene fossils of the Omo Shangura Formation. Paleobiology 12: 311-323. 4. Sillen, A., and Armelagos, G. (eds.) (1991). Second Advanced Seminar in Paleodietary Research. Journal of Archaeological Science 18: 225-416. 1. SiUen, A., Scaly, J. C., and van der Merwe, N. J. (1989). Chemistry and pateodietary research: No more easy answers. American Antiquity 54: 504-512. 29. Spielmann, K. A., Schoeninger, M. J., and Moore, IC (1990). Plains-Pueblo interdependence and human diet at Pecos Pueblo, New Mexico. American Antiquity 55: 745-765. 55. Sullivan, C. H., and Krueger, H. W. (1981). Carbon isotope analysis in separate chemical phases in modern and fossil bone. Nature 292: 333-335. 74. Taufer, I., and Tauferov~, J. (1994). The design of evaluation of assays of trace elements in a fossil bone. Archaeometry 36: 93-113. 70. Thackeray, J. F., van der Merwe, N. J., Lee-Thorp, J. A., Sillen, A., Lanham, J. L., Smith, R., Keyser, A., and Monteiro, P. M. S. (1990). Changes in carbon isotope ratios in the late Permian recorded in therapsid tooth apatite. Nature 347: 751-753. 63. Tieszen, L. L., and Fagre, T. (1993). Effect of diet quality and composition on the isotopic composition of respiratory CO2, bone collagen, bioapatite and soft tissues. In Lambert, J. B., and Grupe, G. (eds.), Prehistoric Human Bone: Archaeology at the Molecular Level, Springer-Verlag, Berlin, pp. 121-155. 41. Tuross, N., and Fogel, M. L. (1994). Stable isotope analysis and subsistence patterns at the Sully site. In Owsley, D. W. and Jantz, R. L. (eds.), Skeletal Biology in the Great Plains: Migration, Warfare, Health and Subsistence, Smithsonian Institution Press, Washington, DC, pp. 283-290. 77. Tuross, N., Behrensmeyer, A. K., and Eanes, E. D. (1989). Strontium increases and crystallinity changes in taphonomic and archaeological bone. Journal of Archaeological Science 16: 661-672. 42. Tykot, R. H., van der Merwe, N. J., and Hammond, N. (1996). Stable isotope analysis of bone collagen, bone apatite, and tooth enamel in the reconstruction of human diet: A case study from Cuello, Belize. In Orna, M. V. (ed.), Archaeological Chemistry: Organic, Inorganic and Biochemical Analysis, ACS Symposium Series 625, American Chemical Society, Washington, DC, pp. 355-365. 32. Ubelaker, D. H., Katzenberg, M. A., and Doyon, L. G. (1995). Status and diet in precontact highland Ecuador. American Journal of Physical Anthropology 97: 403--411. 33. Van der Merwe, N. J., Lee-Thorp, J. A., and Raymond, J. S. (1993). Light, stable isotopes and the subsistence base of Formative cultures at Valdivia, Ecuador. In Lambert, J. B., and Grupe, G. (eds.), Prehistoric Human bone: Archaeology at the Molecular Level, Springer-Verlag, Berlin, pp. 63-97. 43. Walker, P. L., and DeNiro, M. J. (1986). Stable nitrogen and carbon isotope ratios in bone collagen as indices of prehistoric dietary dependence on marine and terrestrial resources in southern California. American Journal of Physical Anthropology 71: 5t-61. 44. Yesner, D. (1988). Subsistence and diet in north-temperate coastal hunter-gatherers: Evidence from the Moshier Island burial site, southwestern Maine. In Kennedy, B. V., and LeMoine, G. M. (eds.), Diet and Subsistence: Current Archaeological Perspectives, Proceedings of the 19th annual conference, University of Calgary Archaeological Association, Calgary, pp. 207-226. 71. Sillen, A., Hall, G., and Armstrong, R. (1995). Strontium/calcium ratios (Sr/Ca) and strontium isotopic ratios (87Sr/86Sr) of Australopithecus robustus and Homo sp. from Swartkrans. Journal of Human Evolution 28: 277-285. Yüklə 36,29 Kb. Dostları ilə paylaş:
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