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Natural History Collections in the Science of the 21st Century


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thorax: mediastinal and pulmonary calcifications [*]. (e) Axial section of the liver [fo.]. (f) Coronal section of the two kidneys [re.]. Images: © Dr. S. Mérigeaud MD/Tridilogy

       4.3.4. Archeoentomology

      Figure 4.10. Location of Calliphoridae diptera puparia (red arrows) (a) on the left thigh of the mummy (photo: © J.B. Huchet), and (b) in the abdominal region, internal view. Image: © Dr. C. Bou

      In parallel, CT examination of the abdomen revealed the presence of innumerable thin-walled oval structures with aerial contents of identical size in the abdominal cavity (Figure 4.10(b)). These structures are unmistakably related to puparia of necrophagous Diptera and indicate an internal colonization of larvae that pupated in situ.

      From a taxonomic point of view, the conformation of the puparia (notably the arrangement of the taste buds and the shape of the respiratory stigmata) indicates that they correspond to immature stages of Calliphoridae diptera (Chrysomyinae), a “pioneer” family of flies of forensic interest, which lay eggs on corpses in the moments following death. Morphologically, these puparia are similar to those of the genus Compsomyiops Townsend, 1918 (Figure 4.11). This taxon, mostly neotropical, has six species, three of which are found in Peru (Gonzalez-Mora et al. 1998). Unlike most of the synanthropic Calliphoridae flies used in forensic science for estimating the postmortem interval (PMI), species of the genus Compsomyiops show a strong preference for environments little or not influenced by human activities (i.e. asynanthropy) (Figueroa-Roa and Linhares 2002; Mariluis et al. 2008).

      Although, as Greenberg and Szyska (1984) point out, the similarities between the immature stages of these two species cannot be denied, data from their biology and from the environmental characteristics of the site where the mummy was found (Reichlen and Reichlen 1950) allow us to hypothesize that the species could correspond to C. arequipensis (Mello) (Figure 4.11).

Photos depict remarkably preserved subfossil puparium of a Calliphoridae fly.

      Figure 4.11. Remarkably preserved subfossil puparium of a Calliphoridae fly (Compsomyops cf. arequipensis (Mello)) from the mummy’s left thigh. Photo © J.B. Huchet

       4.3.5. Cranial trepanation: location, size and mode of operation

Photos depict (a and b) trepanation measurements. (c) Endocranial view of the trepanation site away from the main venous.

      Figure 4.12. (a and b) Trepanation measurements. (c) Endocranial view of the trepanation site away from the main venous (white arrows) and arterial (red arrows) vascular structures. Image: (a) © Dr. C. Bou; images: (b and c) © Dr. S. Mérigeaud MD/Tridilogy

      The edges of the trepanation preserve the trace of 20 microperforations, with a diameter of 0.7 and 1 cm, arranged in a circle, in a regular and confluent manner. A distance of approximately 1 cm between the center of each microperforation is maintained along most of the perimeter of the trepanation, with the exception of an area limited to 3.5 cm where the microperforations are positioned in a more irregular and constricted manner (Figure 4.12(a)).

      In the experimental trepanation, the 20 microperforations were reproduced by rotating a flint tip along an axis vertical to the plane of the cranial vault. The rotations were first performed manually to initiate the perforation, and then with a bow until all perforations were joined (Figure 4.13(a)). The duration of the experiment, to obtain complete trepanation, was over four hours. At the end of the flap removal, the “jagged” morphology of the edges of the experimental trepanation was consistent with that of the mummy. More specifically, the similarity of the marks left by the rotation of the flint at the level of the external and internal tables and the diploe of the cranial vault with those observed on the archaeological case (Figures 4.13(b) and (c)) seems to confirm the technique used.

      Figure 4.13. Experimental extraction of the trepanation flap. (a) Successive steps of the protocol until the bone flap was obtained. (b) Photo of the edges of the trepanation of MNHN-HA-30187. (c) Comparison of the edge obtained experimentally on dry skull. Photos: © Dr. C. Bou

       4.4.1. Identity of the deceased and health status