Progress of Cell Mechanics in 2022 / 医用生物力学

The mechanical microenvironment of cells plays a critical role in regulating the physiological function of cells. Cells in vivo are often subjected to a variety of mechanical forces from their mechanical micro-environment, such as shear, tension, and compression. At the same time, cells can adhere to the extracellular matrix (ECM) through adhesion molecules (such as integrin-ligand binding), and further sense the stiffness of the ECM. Cell mechanics mainly studies the properties and behavior of living cells under mechanical forces, and how they relate to cell functions. This review summarized the advances in cell mechanics in 2022, focusing on integrin-ligand interactions and the effects of matrix stiffness and mechanical forces on cell physiological behavior and morphogenesis.

Cell mechanics in dermatology / 中华皮肤科杂志

Cell mechanics is a new interdiscipline, which focuses on the relationship between cell mechanical properties and cell behaviors, as well as physiological processes in tissues, organs and the body. Through the perception of and response to mechanical signals, cells participate in physiological activities of skin, bones, eyes and other organs, and the occurrence and development of diseases, including the regeneration, reconstruction and adaptive changes of skin tissues and the pathogenesis of various skin diseases. Cell mechanics has become a hot spot in the research of skin diseases in recent years. This review summarizes recent progress in cell mechanics-associated basic research, as well as in its research and application in scars, bedsores, vitiligo, skin tumors, hair diseases, etc., aiming to provide possible methods and strategies for the treatment of skin diseases.

Nuclear elongation correlates with neurite induced cellular elongation during differentiation of SH-SY5Y neural cells / El alargamiento del núcleo se correlaciona con el alargamiento celular inducido por neuritas durante la diferenciación de las células neuronales Sh-Sy5Y

SUMMARY: Cellular differentiation is a highly regulated process that has vast implications for the mechanics of the cell. The interplay between differentiation induced cytoskeletal mechanical changes and strain on the nucleus is a potential cause of gene level changes. This study explores mechanical changes in SH-SY5Y neural cells during differentiation mediated by Retinoic Acid (RA) across Days 0 through 9. Findings suggest that cellular elongation increases 1.92-fold over a 10-day differentiation period, from 48.97 ±16.85µm to 93.96 ± 31.20 µm over 3 repeated trials and across multiple cells analyzed on ImageJ. Nuclear elongation increases less substantially from 17.51 ± 2.71 µm to 23.26 ± 3.10 µm over 3 repeated trials and across multiple cells. Results are statistically significant at a significance level of α = 0.05. This study is one of the first studies to show that during the process of RA mediated neural differentiation in SH-SY5Y neural cells, nuclear elongation is initially not significantly correlated with cellular elongation, but it becomes correlated during the differentiation process with an overall correlation coefficient of 0.4498 at a significance level of α = 0.05. Given the time course of the mechanical changes and the known coupling between the cytoskeleton and nuclear lamina, this study suggests a causative and correlative relationship between neurite-driven cellular elongation and nuclear elongation during neural differentiation.

RESUMEN: La diferenciación celular es un proceso altamente regulado que tiene vastas implicaciones para la mecánica de la célula. La interacción entre los cambios mecánicos citoesqueléticos inducidos por la diferenciación y la tensión en el núcleo es una causa potencial de cambios a nivel genético. Este estudio explora los cambios mecánicos en las células neurales SH-SY5Y durante la diferenciación mediada por el ácido retinoico (RA) durante los días 0 a 9. Los resultados sugieren que el alargamiento celular aumenta 1,92 veces durante un período de diferenciación de 10 días, de 48,97 ± 16,85 µm a 93,96 ± 31,20 µm en 3 ensayos repetidos y en múltiples células analizadas en Image J. El alargamiento nuclear aumenta menos sustancialmente de 17,51 ± 2,71 µm a 23,26 ± 3,10 µm durante 3 ensayos repetidos y en múltiples células. Los resultados son estadísticamente significativos a un nivel de significancia de α = 0,05. Esta investigación es uno de los primeros estudios en demostrar que durante el proceso de diferenciación neural mediada por RA en las células neurales SH-SY5Y, el alargamiento nuclear inicialmente no se correlaciona significativamente con el alargamiento celular, pero se correlaciona durante el proceso de diferenciación con un coeficiente de correlación global de 0,4498 a un nivel de significancia de α = 0,05. Dado el curso temporal de los cambios mecánicos y el acoplamiento conocido entre el citoesqueleto y la lámina nuclear, este estudio sugiere una relación causal y correlativa entre el alargamiento celular impulsado por neuritas y el alargamiento nuclear durante la diferenciación neural.

Microfluidic Chip Separation and Physical Property Measurement of Circulating Tumor Cells / 医用生物力学

Objective To establish a new method to measure the elastic modulus of living circulating tumor cells (CTCs) by micropipette aspiration. Methods Living CTCs were enriched by commercial microfluidic chips and identified individually using EpCAM antibody under fluorescence microscope. The elastic modulus of CTCs was measured using micropipette aspiration and compared with cancer cell lines. Results For the elastic modulus of different cancer cell lines, heterogeneity was found not only between the different types of cancer cell lines but also inside the same cell line. The CTCs in breast cancer had a smaller elasticity modulus compared with MCF-7 cancer cell line. Conclusions This method can measure the elastic modulus of living CTCs, which provides cell mechanics data for studying the relationship between physical properties of CTCs and diagnosis of cancers, as well as developing the physical biomarkers of tumor cells.

Numeric reconstruction of 2D cellular actomyosin network from substrate displacement

Introduction: One of the fundamental structural elements of the cell is the cytoskeleton. Along with myosin, actin microfilaments are responsible for cellular contractions, and their organization may be related to pathological changes in myocardial tissue. Due to the complexity of factors involved, numerical modeling of the cytoskeleton has the potential to contribute to a better understanding of mechanical cues in cellular activities. In this work, a systematic method was developed for the reconstruction of an actomyosin topology based on the displacement exerted by the cell on a flexible substrate. It is an inverse problem which could be considered a phenomenological approach to traction force microscopy (TFM). Methods An actomyosin distribution was found with a topology optimization method (TOM), varying the material density and angle of contraction of each element of the actomyosin domain. The routine was implemented with a linear material model for the bidimensional actomyosin elements and tridimensional substrate. The topology generated minimizes the nodal displacement squared differences between the generated topology and experimental displacement fields obtained by TFM. The structure resulting from TOM was compared to the actin structures observed experimentally with a GFP-attached actin marker. Results The optimized topology reproduced the main features of the experimental actin and its squared displacement differences were 11.24 µm2, 27.5% of the sum of experimental squared nodal displacements (40.87 µm2). Conclusion This approach extends the literature with a model for the actomyosin structure capable of distributing anisotropic material freely, allowing heterogeneous contraction over the cell extension.