Morphological Characterisation And Molecular Sex Determination Of Human Remains From The 15^th–17^th Centuries In Latvia

Actiņš, A., Lūsēns, M., Rudoviča, V., Vīksna, A., Zariņa, G. (2009). Rīgas Sv. Ģertrūdes baznīcas kapsētas augsnes paraugu ķīmiskā sastāva izpēte [The study of chemical composition of soil samples from Riga St Gertrude’s Church cemetery]. In: Senā Rīga 6: Pilsētas arheoloģija, arhitektūra (59.–70. lpp). Rīga: Latvijas vēstures institūta apgāds (in Latvian).Search in Google Scholar

Ascádi, G., Nemeskéri, J. (1970). History of Human Lifespan and Mortality. Budapest: Akademiai Kiado.Search in Google Scholar

Brickley, M., Ives, R. (2008). The Bioarchaeology of Metabolic Bone Disease. Oxford: Academic Press.Search in Google Scholar

Bauer, C. M., Niederstätter, H., McGlynn, G., Stadler, H., Parson, W. (2013). Comparison of morphological and molecular genetic sex-typing on mediaeval human skeletal remains. Forensic Sci. Int. Genet., 7 (6), 581–586.10.1016/j.fsigen.2013.05.005382002023941903Search in Google Scholar

Brooks, S., Suchey, J. M. (1990). Skeletal age determination based on the os pubis: A comparison of the Acsadi-Nemeskeri and Suchey-Brooks methods. Hum. Evol., 5, 227–238.10.1007/BF02437238Search in Google Scholar

Bruzek, J. (2002). A method for visual determination of sex, using the human hip bone. Amer. J. Phys. Anthropol., 117, 157–168.10.1002/ajpa.1001211815949Search in Google Scholar

Buckberry, J. L., Chamberlain, A. T. (2002). Age estimation from the auricular surface of the ilium: A revised method. J. Phys. Anthropol., 119, 231–239.10.1002/ajpa.1013012365035Search in Google Scholar

Buikstra, J. E., Ubelaker, D. H. (1994). Standards for data collection from human skeletal remains. Proceedings of a Seminar at the Field Museum of Natural History (Arkansas Archaeological Survey Research Series, Vol. 33). Fayetteville: Arkansas Archeological Survey. 218 pp.Search in Google Scholar

Cox, M., Mays, S. (2000). Human Osteology in Archaeology and Forensic Science. Greenwich Medical Media Ltd, London. 548 pp.Search in Google Scholar

Donoghue, H. D. (2008). Molecular palaeopathology of human infectious disease. In: Advances of Human Palaeopathology. Phinasi, R., Mays, S. (eds.). Chichester: John Wiley & Sons Ltd., pp. 147–176.Search in Google Scholar

Genove´s, S. (1959). L’estimation des diffe´rences sexuelles dans l’os coxal; differences me´triques et diffe´rences morphologiques [The estimation of sex differences in the hip bone; metric and morphological differences]. Bull. Mem. Soc. Anthropol. Paris, 10, 3–95 (in French).Search in Google Scholar

Grigorenko, A. P., Borinskaya, S. A., Yankovsky, N. K., Rogaev, E. I. (2009). Achievements and peculiarities in studies of ancient DNA and DNA from complicated forensic specimens. Acta Naturae, 1 (3), 58–69.10.32607/20758251-2009-1-3-58-69Search in Google Scholar

Haas-Rochholz, H., Weiler, G. (1997) Additional primer sets for an amelogenin gene PCR-based DNA-sex test. Int. J. Legal Med., 110 (6), 312–315.10.1007/s0041400500949387013Search in Google Scholar

Hoyme, L. E., Iscan, M. Y. (1989). Determination of sex and race: Accuracy and assumptions. In: Reconstruction of Life from the Skeleton. Iscan, M. Y., Kennedy, K. A. D. (eds.). New York: Wiley & Sons, pp. 53–93.Search in Google Scholar

Li, S., Feng, T., Fu, L., Li, Z., Lou, C., Zhang, X., Ma, C., Cong, B. (2012). Pyrosequencing of a short fragment of the amelogenin gene for gender identification. Mol. Biol. Rep., 39 (6), 6949–6957.10.1007/s11033-012-1522-222311027Search in Google Scholar

Lovejoy, C. O., Meindl, R. S., Mensforth, R. P., Barton, T. J. (1985) Multifactorial determination of skeletal age at death: A method and blind tests of its accuracy. Amer. J. Phys. Anthrop., 68, 1–14.Search in Google Scholar

Lūsēns, M. (2008). Arheoloģiskie pētījumi Sv. Ģertrūdes baznīcas kapsētā Rīgā [Archaeological studies of St Gertrude Church cemetery in Riga]. In: Arheologu pētījumi Latvijā 2006. un 2007. gadā. Zinātne, Rīga, pp. 143–151 (in Latvian).Search in Google Scholar

Mannucci, A., Sullivan, K. M., Ivanov, P. L., Gill, P. (1994) Forensic application of a rapid and quantitative DNA sex test by amplification of the X-Y homologous gene amelogenin. Int. J. Leg. Med., 106, 190–193.Search in Google Scholar

Mays, S. (1992). Taphonomic factors in a human skeletal assemblage. Circaea, 9(2), 54–58.Search in Google Scholar

Meindl, R. S., Lovejoy, C. O. (1985). Ectocranial suture closure: A revised method for the determination of skeletal age at death based on the lateral–anterior sutures. Amer. J. Phys. Anthropol., 8, 57–66.10.1002/ajpa.13306801064061602Search in Google Scholar

Milner, G. R. (1992). Determination of Skeletal Age and Sex. Manual prepared for the Dickson Mounds skeletal reburial project. Springfield: Illinois State Museum,Search in Google Scholar

Phenice, T. W. (1969). A newly developed visual methods of sexing the os pubis. Amer. J. Phys. Anthropol., 30, 297–301.10.1002/ajpa.13303002145772048Search in Google Scholar

Santos, F. R., Pandya, A., Tyler-Smith, C. (1998). Reliability of DNA-based sex tests. Nat. Genet.18, 103.10.1038/ng0298-1039462733Search in Google Scholar

Saunders, S. R., Fitzgerald, C., Rogers, T., Dudar, C., McKillop, H. (1992). A test of several methods of skeletal age estimation using a documented archaelogical sample. Can. Soc. For. Sci., 25, 97–118.Search in Google Scholar

Spirģis, R. (2012). Rīgas Sv. Pētera baznīcas kapsētas apbedījumu stratigrāfija [Stratigraphy of the Riga’s St. Peter's Church cemetery burial]. In: Senā Rīga 7: Pētījumi pilsētas arheoloģijā un vēsturē (179.–225. lpp.). Rīga: Latvijas vēstures institūta apgāds (in Latvian).Search in Google Scholar

Stojanowski, C. M., Seidemann, R. M., Doran, G. H. (2002). Differential skeletal preservation at Windover Pond: Causes and consequences. Amer. J. Phys. Anthropol., 119, 15–26.10.1002/ajpa.1010112209570Search in Google Scholar

Tozzo, P., Giuliodori, A., Corato, S., Ponzano, E., Rodriguez, D., Caenazzo, L. (2013). Deletion of amelogenin Y-locus in forensics: Literature revision and description of a novel method for sex confirmation. J. Forensic. Leg. Med., 20 (5), 387–391.10.1016/j.jflm.2013.03.01223756502Search in Google Scholar

Waldron, T. (1987). The relative survival of the human skeleton: Implications for palaeopathology. In: Death, Decay and Reconstruction: Approaches to Archaeology and Forensic Science (pp. 55–64). Manchester: Manchester University Press.Search in Google Scholar

Willerslev, E., Cooper, A. (2005). Ancient DNA. Proc. R. Soc., 272, 3–16.Search in Google Scholar

Ye, J., Ji, A., Parra, E. J., Zheng, X., Jiang, C., Zhao, X., Hu, L., Tu, Z. (2004). A simple and efficient method for extracting DNA from old and burned bone. J. Forensic. Sci., 49 (4), 754–759.10.1520/JFS2003275Search in Google Scholar

Zapico, S. C., Ubelaker, D. H. (2013). Sex determination from dentin and pulp in a medicolegal context. J. Amer. Dent. Assoc., 144 (12), 1379–1385.10.14219/jada.archive.2013.007424282268Search in Google Scholar