Translating microcalcification biomarker information into the laboratory: A preliminary assessment utilizing core biopsies obtained from sites of mammographic calcification

Iain D Lyburn; Robert Scott; Eleanor Cornford; Pascaline Bouzy; Nicholas Stone; Charlene Greenwood; Ihsanne Bouybayoune; Sarah E Pinder; Keith Rogers

doi:10.1016/j.heliyon.2024.e27686

Translating microcalcification biomarker information into the laboratory: A preliminary assessment utilizing core biopsies obtained from sites of mammographic calcification

Heliyon. 2024 Mar 11;10(6):e27686. doi: 10.1016/j.heliyon.2024.e27686. eCollection 2024 Mar 30.

Authors

Iain D Lyburn¹, Robert Scott², Eleanor Cornford¹, Pascaline Bouzy³, Nicholas Stone³, Charlene Greenwood⁴, Ihsanne Bouybayoune⁵, Sarah E Pinder⁵, Keith Rogers²

Affiliations

¹ Gloucestershire Hospitals NHS Foundation Trust, Cheltenham, United Kingdom.
² Cranfield Forensic Institute, Cranfield University, Swindon, United Kingdom.
³ School of Physics and Astronomy, University of Exeter, Exeter, United Kingdom.
⁴ School of Chemical and Physical Sciences, Keele University, Staffordshire, United Kingdom.
⁵ School of Cancer and Pharmaceutical Sciences, King's College London, London, United Kingdom.

Abstract

Rationale and objectives: The potential of breast microcalcification chemistry to provide clinically valuable intelligence is being increasingly studied. However, acquisition of crystallographic details has, to date, been limited to high brightness, synchrotron radiation sources. This study, for the first time, evaluates a laboratory-based system that interrogates histological sections containing microcalcifications. The principal objective was to determine the measurement precision of the laboratory system and assess whether this was sufficient to provide potentially clinical valuable information.

Materials and methods: Sections from 5 histological specimens from breast core biopsies obtained to evaluate mammographic calcification were examined using a synchrotron source and a laboratory-based instrument. The samples were chosen to represent a significant proportion of the known breast tissue, mineralogical landscape. Data were subsequently analysed using conventional methods and microcalcification characteristics such as crystallographic phase, chemical deviation from ideal stoichiometry and microstructure were determined.

Results: The crystallographic phase of each microcalcification (e.g., hydroxyapatite, whitlockite) was easily determined from the laboratory derived data even when a mixed phase was apparent. Lattice parameter values from the laboratory experiments agreed well with the corresponding synchrotron values and, critically, were determined to precisions that were significantly greater than required for potential clinical exploitation.

Conclusion: It has been shown that crystallographic characteristics of microcalcifications can be determined in the laboratory with sufficient precision to have potential clinical value. The work will thus enable exploitation acceleration of these latent microcalcification features as current dependence upon access to limited synchrotron resources is minimized.

Keywords: Biomarker; Crystallography; Microcalcification; X-ray scatter.