Biomineral electron backscatter diffraction for palaeontology

Cusack, Maggie

doi:10.1111/pala.12222

Cited by 28 publications

(30 citation statements)

References 75 publications

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“…, ). It is also widely applicable in studies on palaeontological and neontological biomineralization, especially in carbonate biominerals (Cusack ; Pérez‐Huerta et al . ).…”

Section: The Ebsd Mapping Images Of Dinosaur Eggshell Available In Thmentioning

confidence: 99%

“…). In general, vertebrates utilize calcium phosphate as the building blocks of their internal skeleton whereas invertebrates use calcium carbonate for their shell construction (Cusack & Freer ; Cusack ; Athanasiadou et al . ).…”

Section: The Ebsd Mapping Images Of Dinosaur Eggshell Available In Thmentioning

confidence: 99%

“…). Biomineralization studies using EBSD have been mainly concentrated on invertebrates such as bivalves, brachiopods, corals and trilobites (Cusack , and references therein). However, EBSD can also be extensively applied to calcium carbonate biominerals found in the sauropsid vertebrates: namely, their eggshells.…”

Section: The Ebsd Mapping Images Of Dinosaur Eggshell Available In Thmentioning

confidence: 99%

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Electron backscatter diffraction (EBSD) analysis of maniraptoran eggshells with important implications for microstructural and taphonomic interpretations

2019

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Electron backscatter diffraction (EBSD) is a useful tool for gathering crystallographic information from carbonate biominerals because it maps out the orientation of crystal grains very precisely. EBSD has become popular in invertebrate palaeontology but its application in vertebrate palaeontology remains limited. However, the study of fossil eggshells is a field where EBSD has wide potential applicability and provides a quantitative approach to fossil eggshell research as well as new qualitative data. Here we analyse fossil and extant maniraptoran dinosaur eggshells using EBSD analysis emphasizing four different aspects. The mapping imaging clarifies previously ambiguous characters such as squamatic ultrastructure and allows a more objective evaluation of avian and non-avian maniraptoran eggshell. In particular, our results imply that the presence of an external zone in the manirpatoran eggshell is not diagnostic of avian eggshell. EBSD analysis can be also used for differentiating true pore canals from cracks in the eggshell radial section, thereby determining the biological genuineness or otherwise of a pore-like structure. Finally, the misorientation angle distribution of the material shows a clear dichotomy that may reflect reproductive brooding strategy, although further studies on contact incubation of palaeognaths and neognaths are needed to confirm this.

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“…, ). It is also widely applicable in studies on palaeontological and neontological biomineralization, especially in carbonate biominerals (Cusack ; Pérez‐Huerta et al . ).…”

Section: The Ebsd Mapping Images Of Dinosaur Eggshell Available In Thmentioning

confidence: 99%

Section: The Ebsd Mapping Images Of Dinosaur Eggshell Available In Thmentioning

confidence: 99%

Section: The Ebsd Mapping Images Of Dinosaur Eggshell Available In Thmentioning

confidence: 99%

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Electron backscatter diffraction (EBSD) analysis of maniraptoran eggshells with important implications for microstructural and taphonomic interpretations

2019

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“…For a more detailed description about the method, see Prior et al (1999). For a discussion of applications to biological specimens, see e.g., Griesshaber et al (2010) and Cusack (2016).…”

Section: Principles Of Electron Backscatter Diffraction (Ebsd)mentioning

confidence: 99%

Distinguishing Biologically Controlled Calcareous Biomineralization in Fossil Organisms Using Electron Backscatter Diffraction (EBSD)

et al. 2018

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Although carbonate-precipitating cyanobacteria are ubiquitous in aquatic ecosystems today, the criteria used to identify them in the geological record are subjective and rarely testable. Differences in the mode of biomineralization between cyanobacteria and eukaryotes, i.e., biologically induced calcification (BIM) vs. biologically controlled calcification (BCM), result in different crystallographic structures which might be used as a criterion to test cyanobacterial affinities. Cyanobacteria are often used as a "wastebasket taxon," to which various microfossils are assigned. The lack of a testable criterion for the identification of cyanobacteria may bias their fossil record severely. We employed electron backscatter diffraction (EBSD) to investigate the structure of calcareous skeletons in two microproblematica widespread in Palaeozoic marine ecosystems: Rothpletzella, hypothesized to be a cyanobacterium, and an incertae sedis microorganism Allonema. We used a calcareous trilobite shell as a BCM reference. The mineralized structure of Allonema has a simple single-layered structure of acicular crystals perpendicular to the surface of the organism. The c-axes of these crystals are parallel to the elongation and thereby normal to the surface of the organism. EBSD pole figures and misorientation axes distribution reveal a fiber texture around the c-axis with a small degree of variation (up to 30 • ), indicating a highly ordered structure. A comparable pattern was found in the trilobite shell. This structure allows excluding biologically induced mineralization as the mechanism of shell formation in Allonema. In Rothpletzella, the c-axes of the microcrystalline sheath show a broader clustering compared to Allonema, but still reveal crystals tending to be perpendicular to the surface of the organism. The misorientation axes of adjacent crystals show an approximately random distribution. Rothpletzella also shares morphological similarities with extant cyanobacteria. We propose that the occurrence of a strong misorientation relationship between adjacent crystals with misorientation axes clustering around the c-axis can be used as a proxy for the degree of control exerted by an organism on its mineralized structures. Therefore, precisely constrained distributions of misorientations (misorientation angle and misorientation axis) may be used to identify BCM in otherwise problematic fossils and can be used to ground-truth the cyanobacterial affinities commonly proposed for problematic extinct organisms.

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“…Päßler et al (2018) documented poorly ordered, weak parallel arrangement of crystals with a nearly random distribution of misorientation angles between adjacent crystals. Such a texture is less ordered and less diagenetically stable than more constrained crystallographic textures of metazoans (Griesshaber et al 2010;Cusack 2016;Päßler et al 2018). Poorly ordered structure might have resulted in the relative instability of Rothpletzella skeletons and its potential dissolution in conditions of low redox potential.…”

Section: Comparisons and Affinities Of The Fossilsmentioning

confidence: 99%

Enigmatic encrusting fossils from the Upper Devonian of Russia: probable Rothpletzella microproblematica preserved in three dimensions

Zatoń

Jarochowska

2018

Historical Biology

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Intriguing microfossils encrusting certain Upper Devonian brachiopod shells from the Central Devonian Field, Russia, are reported for the first time. The fossils are pyritized, have fan-shaped morphologies and are formed by tightly-packed branches which divide dichotomously at different points in their development. The organisms preserved grew horizontally on shelly substrates. Comparisons with similar fossils known from the literature indicate that they do not represent any animal taxon commonly encrusting hard substrates. Instead, the morphology, organization and growth mode of these fossils are most similar to microfossils known under the name Rothpletzella, which so far have only been known from thin sections. Rothpletzella is a problematicum for which algal affinities have been proposed. The preserved branches of the fossils described here are too large for cyanobacterial cells. Their large size suggests their placement, along with other described Rothpletzella fossils, within the green algae order Bryopsidales. It is suggested that originally, these organisms 2 possessed thalli encased within a thin, delicate calcified sheath. After burial the thalli underwent pyritization via sulphate reduction mediated by bacterial activity within low pH, dysoxic microenvironment, and their sheath dissolved. As three-dimensionally preserved, these algae provide a new, previously unrecognized, component within the Devonian encrusting communities.

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Biomineral electron backscatter diffraction for palaeontology

Cited by 28 publications

References 75 publications

Electron backscatter diffraction (EBSD) analysis of maniraptoran eggshells with important implications for microstructural and taphonomic interpretations

Electron backscatter diffraction (EBSD) analysis of maniraptoran eggshells with important implications for microstructural and taphonomic interpretations

Distinguishing Biologically Controlled Calcareous Biomineralization in Fossil Organisms Using Electron Backscatter Diffraction (EBSD)

Enigmatic encrusting fossils from the Upper Devonian of Russia: probable Rothpletzella microproblematica preserved in three dimensions

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