Three-Dimensional Characterization of Red Blood Cell Shape via Stereological Methods
DOI:
https://doi.org/10.5566/ias.3732Keywords:
bending energy, red blood cells, 3D confocal microscopy, geometric sampling, integral geometry, stereologyAbstract
Red blood cells (RBCs) exhibit a variety of morphologies that reflect their physiological or pathological state. Accurate classification of these shapes is essential for clinical diagnostics and hematological research. While most current classification methods rely on two-dimensional (2D) imaging, typically obtained through smear preparations that distort the natural three-dimensional (3D) structure of RBCs, these approaches often fail to capture diagnostically relevant 3D shape information and may lead to misclassification.
In this work, we propose a novel method for 3D shape classification of RBCs based on two geometric descriptors: the spherical shape factor (F) and the bending energy (E). These descriptors are estimated directly from confocal microscopy image stacks using stereological techniques, thus avoiding the need for full 3D reconstruction. This stereological framework provides efficient, reproducible, and unbiased estimates of morphological features from sets of parallel planar sections.
We demonstrate the effectiveness of this approach on a dataset that includes both standard SDE cell types (discocytes, stomatocytes, spherocytes, and echinocytes) and various abnormal morphologies.
References
Angelov B and Mladenov I (2000). On the geometry of red blood cell. Geometry, Integrability and Quantization.September 1-10, 1999, Varna, Bulgaria Ivaïlo M. Mladenov and Gregory L. Naber, Editors Coral Press, Sofia:27-46
Bernard Y (2016). Noether’s theorem and the Willmore functional. Advances in Calculus of Variations 9(3):217-234
Bogdanova A, Kaestner L, Simionato G, Wickrema A, Makhro A (2020). Heterogeneity of Red Blood Cells: Causes and Consequences. Front Physiol 11:392
Canham R (1970). The Minimum Energy of Bending as a Possible Explanation of the Biconcave Shape of the Human Red Blood Cell. J. Theor. Biol 26:61-81.
Constantino BT (2015). Reporting and grading of abnormal red blood cell morphology. Int J Lab Hematol 37(1):1-7
Cruz-Orive LM (2024). Stereology. Theory and Applications, Interdisciplinary Applied Mathematics, Volume 59, Springer
do Carmo MP (1976). Differential Geometry of Curves and Surface. Prentice Hall, Englewood Cliffs, New York
Foy BH, Stefely JA, Bendapudi PK, Hasserjian RP, Al-Samkari H, Louissaint A, Fitzpatrick MJ, Hutchison B, Mow C, Collins J, Patel HR, Patel CH, Patel N, Ho SN, Kaufman RM, Dzik WH, Higgins JM, Makar RS (2023). Computer vision quantitation of erythrocyte shape abnormalities provides diagnostic, prognostic, and mechanistic insight. Blood Adv 7(16):4621–4630
Gual-Arnau X, Ibáñez Gual MV, Monterde J (2017). Curvature approximation from parabolic sectors. Image Analysis and Stereology 36(3):233--241
Gual-Vayà Ll (2024). Classification of Red Blood Cells From a Geometric Morphometric Study. Image Analysis and Stereology 43(1):109–119
Jaferzadeh K, Sim M, Kim N Moon I (2019). Quantitative analysis of three-dimensional morphology and membrane dynamics of red blood cells during temperature elevation. Sci Rep 9:14062
Kindratenko VV (2003). On Using Functions to Describe the Shape. Journal of Mathematical Imaging and Vision 18:225–245
Kurz A, Müller H, Katherc JN, Schneider L, Bucher TC, Brinker TJ (2024). 3-Dimensional Reconstruction From Histopathological Sections: A Systematic Review. Lab Invest 104:102049
Larkin TJ, Pages G, Chapman BE, Rasko, JEJ, Kuchel PW (2013). NMR q-space analysis of canonical shapes of human erythrocytes: stomatocytes, discocytes, spherocytes and echinocytes. Eur Biophys J 42:3–16.
Lin B, Jin D, Socorro-Borges, MA (2022). 3D surface reconstruction of the femur and tibia from parallel 2D contours. J Orthop Surg Res 17:145
Pages G, Yau TW, Kuchel PW (2010). Erythrocyte shape reversion from echinocytes to discocytes: Kinetics via fast-measurement NMR diffusion-diffraction. Magn Reson Med 64:645–652
Paz-Soto Y, Herold-Garcia S, Gual-Arnau X, Jaume-i-Capó A, MGonzález-Hidalgo M (2025). An efficient heuristic for geometric analysis of cell deformations, Computers in Biology and Medicine 186:109709
Ritoré M, Sinestrari C (2010). The classical isoperimetric inequality in Euclidean space. In: Mean Curvature Flow and Isoperimetric Inequalities. Advanced Courses in Mathematics — CRM Barcelona. Birkhäuser Basel
Ruef P, Linderkamp O (1999). Deformability and Geometry of Neonatal Erythrocytes with Irregular Shapes. Pediatr Res 45:114–119
Santal'o LA (1976). Integral Geometry and Geometric Probability, Addison-Wesley Publishing Company Inc. London
Simionato G, Hinkelmann K, Chachanidze R, Bianchi P, Fermo E, van Wijk R, Leonetti M, Wagner C, Kaestner L, Quint S (2021). Red blood cell phenotyping from 3D confocal images using artificial neural networks. PLoS Comput Biol 17(5):e1008934
Toda MD (2018). Willmore Energy and Willmore Conjecture, Taylor and Francis. Boca Raton.
Waibel DJE, Kiermeyer N, Atwell S, Sadafi A, Meier M, Marr C (2022). SHAPR predicts 3D cell shapes from 2D microscopic images. iScience, 25(11):105298
Westcott H (1987). Model geometries for sickle erythrocytes. Bulletin of Mathematical Biology 49(4):403-411
Willmore TJ (2002). Riemannian geometry, Oxford University Press, New York
Downloads
Published
Data Availability Statement
The dataset used in this study consists of
confocal microscopy sections of red blood cells
(RBCs) from both healthy individuals and patients
with various pathologies. It is publicly available
at https://doi.org/10.5281/zenodo.4670205
Issue
Section
License
Copyright (c) 2025 Lluisa Gual-Vaya
This work is licensed under a Creative Commons Attribution 4.0 International License.
How to Cite
