Cell deformability is a well-established marker of cell states for diagnostic purposes. However, the measurement of a wide range of different deformability levels is still challenging, especially in cancer, where a large heterogeneity of rheological/mechanical properties is present. Therefore, a simple, versatile and cost-effective recognition method for variable rheological/mechanical properties of cells is needed. Here, we introduce a new set of in-flow motion parameters capable of identifying heterogeneity among cell deformability, properly modified by the administration of drugs for cytoskeleton destabilization. Firstly, we measured cell deformability by identification of in-flow motions, rolling (R), tumbling (T), swinging (S) and tank-treading (TT), distinctively associated with cell rheological/mechanical properties. Secondly, from a pool of motion and structural cell parameters, an unsupervised machine learning approach based on principal component analysis (PCA) revealed dominant features: the local cell velocity (V-Cell/V-Avg), the equilibrium position (Y-Eq) and the orientation angle variation (Delta phi). These motion parameters clearly defined cell clusters in terms of motion regimes corresponding to specific deformability. Such correlation is verified in a wide range of rheological/mechanical properties from the elastic cells moving like R until the almost viscous cells moving as TT. Thus, our approach shows how simple motion parameters allow cell deformability heterogeneity recognition, directly measuring rheological/mechanical properties.

Cell deformability heterogeneity recognition by unsupervised machine learning from in-flow motion parameters / Maremonti, Mi; Dannhauser, D; Panzetta, V; Netti, P; Causa, F. - In: LAB ON A CHIP. - ISSN 1473-0197. - 22:(2022), pp. 4871-4881. [10.1039/d2lc00902a]

Cell deformability heterogeneity recognition by unsupervised machine learning from in-flow motion parameters

MI Maremonti;D Dannhauser
;
V Panzetta;P Netti;F Causa
2022

Abstract

Cell deformability is a well-established marker of cell states for diagnostic purposes. However, the measurement of a wide range of different deformability levels is still challenging, especially in cancer, where a large heterogeneity of rheological/mechanical properties is present. Therefore, a simple, versatile and cost-effective recognition method for variable rheological/mechanical properties of cells is needed. Here, we introduce a new set of in-flow motion parameters capable of identifying heterogeneity among cell deformability, properly modified by the administration of drugs for cytoskeleton destabilization. Firstly, we measured cell deformability by identification of in-flow motions, rolling (R), tumbling (T), swinging (S) and tank-treading (TT), distinctively associated with cell rheological/mechanical properties. Secondly, from a pool of motion and structural cell parameters, an unsupervised machine learning approach based on principal component analysis (PCA) revealed dominant features: the local cell velocity (V-Cell/V-Avg), the equilibrium position (Y-Eq) and the orientation angle variation (Delta phi). These motion parameters clearly defined cell clusters in terms of motion regimes corresponding to specific deformability. Such correlation is verified in a wide range of rheological/mechanical properties from the elastic cells moving like R until the almost viscous cells moving as TT. Thus, our approach shows how simple motion parameters allow cell deformability heterogeneity recognition, directly measuring rheological/mechanical properties.
2022
Cell deformability heterogeneity recognition by unsupervised machine learning from in-flow motion parameters / Maremonti, Mi; Dannhauser, D; Panzetta, V; Netti, P; Causa, F. - In: LAB ON A CHIP. - ISSN 1473-0197. - 22:(2022), pp. 4871-4881. [10.1039/d2lc00902a]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11588/901276
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