Microscopical and elemental FESEM and Phenom ProX-SEM-EDS analysis of osteocyte- and blood vessel-like microstructures obtained from fossil vertebrates of the Eocene Messel Pit, Germany
Artículo académico
The Eocene (∼48 Ma) Messel Pit in Germany is a UNESCO World Heritage Sitebecause of its exceptionally preserved fossils, including vertebrates, invertebrates,and plants. Messel fossil vertebrates are typically characterized by their articulatedstate, and in some cases the skin, hair, feathers, scales and stomach contents arealso preserved. Despite the exceptional macroscopic preservation of Messel fossilvertebrates, the microstructural aspect of these fossils has been poorly explored. Inparticular, soft tissue structures such as hair or feathers have not been chemicallyanalyzed, nor have bone microstructures. I report here the preservation and recoveryof osteocyte-like and blood vessel-like microstructures from the bone of Messel Pitspecimens, including the turtles Allaeochelys crassesculpta and Neochelys franzeni,the crocodile Diplocynodon darwini, and the pangolin Eomanis krebsi. I used aField Emission Scanning Electron Microscope (FESEM) and a Phenom ProXdesktop scanning electron microscope (LOT-QuantumDesign) equipped with athermionic CeB6 source and a high sensitivity multi-mode backscatter electron (BSE)for microscopical and elemental characterization of these bone microstructures.Osteocyte-like and blood vessel-like microstructures are constituted by a thin layer(∼50 nm thickness), external and internal mottled texture with slightly markedstriations. Circular to linear marks are common on the external surface of theosteocyte-like microstructures and are interpreted as microbial troughs. Iron (Fe)is the most abundant element found in the osteocyte-like and blood vessel-likemicrostructures, but not in the bone matrix or collagen fibril-like microstructures.The occurrence of well-preserved soft-tissue elements (at least their physical form)establishes a promising background for future studies on preservation of biomolecules(proteins or DNA) in Messel Pit fossils.
The Eocene (∾48 Ma) Messel Pit in Germany is a UNESCO World Heritage Site because of its exceptionally preserved fossils, including vertebrates, invertebrates, and plants. Messel fossil vertebrates are typically characterized by their articulated state, and in some cases the skin, hair, feathers, scales and stomach contents are also preserved. Despite the exceptional macroscopic preservation of Messel fossil vertebrates, the microstructural aspect of these fossils has been poorly explored. In particular, soft tissue structures such as hair or feathers have not been chemically analyzed, nor have bone microstructures. I report here the preservation and recovery of osteocyte-like and blood vessel-like microstructures from the bone of Messel Pit specimens, including the turtles Allaeochelys crassesculpta and Neochelys franzeni , the crocodile Diplocynodon darwini , and the pangolin Eomanis krebsi . I used a Field Emission Scanning Electron Microscope (FESEM) and a Phenom ProX desktop scanning electron microscope (LOT-QuantumDesign) equipped with a thermionic CeB6 source and a high sensitivity multi-mode backscatter electron (BSE) for microscopical and elemental characterization of these bone microstructures. Osteocyte-like and blood vessel-like microstructures are constituted by a thin layer (∾50 nm thickness), external and internal mottled texture with slightly marked striations. Circular to linear marks are common on the external surface of the osteocyte-like microstructures and are interpreted as microbial troughs. Iron (Fe) is the most abundant element found in the osteocyte-like and blood vessel-like microstructures, but not in the bone matrix or collagen fibril-like microstructures. The occurrence of well-preserved soft-tissue elements (at least their physical form) establishes a promising background for future studies on preservation of biomolecules (proteins or DNA) in Messel Pit fossils.