Cell Shape and Forces in Elastic and Structured Environments: From Single Cells to Organoids

Link, Rabea; Weißenbruch, Kai; Tanaka, Motomu; Bastmeyer, Martin; Schwarz, Ulrich S.

doi:10.1002/adfm.202302145

Cited by 7 publications

(6 citation statements)

References 329 publications

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“…Some models hypothesize dynamics such as protrusion formation and shape oscillations to arise from signaling especially by small GTPases ( Danuser et al, 2013 ; Rappel and Edelstein-Keshet, 2017 ; Bolado-Carrancio et al, 2020 ; Shaebani et al, 2020 ). Another group of models considers the signaling state of the cell as constant, setting the parameters for a dynamic mechanical system of cytoplasmic and F-actin flows, Myosin II based contraction and membrane dynamics ( Kruse et al, 2005 ; Safran et al, 2005 ; Jülicher et al, 2007 ; Gholami et al, 2008 ; Enculescu et al, 2010 ; Zimmermann et al, 2010 ; Shaebani et al, 2020 ; Link et al, 2023 ). The modeling approaches have been described in several reviews ( Romanczuk et al, 2012 ; Ryan et al, 2012 ; Danuser et al, 2013 ; Alert and Trepat, 2020 ; Shaebani et al, 2020 ; Link et al, 2023 ; Zöttl and Stark, 2023 ).…”

Section: What Can Biophysical Modeling Contribute To Understanding Mo...mentioning

confidence: 99%

“…Another group of models considers the signaling state of the cell as constant, setting the parameters for a dynamic mechanical system of cytoplasmic and F-actin flows, Myosin II based contraction and membrane dynamics ( Kruse et al, 2005 ; Safran et al, 2005 ; Jülicher et al, 2007 ; Gholami et al, 2008 ; Enculescu et al, 2010 ; Zimmermann et al, 2010 ; Shaebani et al, 2020 ; Link et al, 2023 ). The modeling approaches have been described in several reviews ( Romanczuk et al, 2012 ; Ryan et al, 2012 ; Danuser et al, 2013 ; Alert and Trepat, 2020 ; Shaebani et al, 2020 ; Link et al, 2023 ; Zöttl and Stark, 2023 ). Here, we focus on modeling studies specifically for 1D motion.…”

Section: What Can Biophysical Modeling Contribute To Understanding Mo...mentioning

confidence: 99%

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Mesenchymal cell migration on one-dimensional micropatterns

Heyn,

Rädler,

Falcke

2024

Front. Cell Dev. Biol.

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Quantitative studies of mesenchymal cell motion are important to elucidate cytoskeleton function and mechanisms of cell migration. To this end, confinement of cell motion to one dimension (1D) significantly simplifies the problem of cell shape in experimental and theoretical investigations. Here we review 1D migration assays employing micro-fabricated lanes and reflect on the advantages of such platforms. Data are analyzed using biophysical models of cell migration that reproduce the rich scenario of morphodynamic behavior found in 1D. We describe basic model assumptions and model behavior. It appears that mechanical models explain the occurrence of universal relations conserved across different cell lines such as the adhesion-velocity relation and the universal correlation between speed and persistence (UCSP). We highlight the unique opportunity of reproducible and standardized 1D assays to validate theory based on statistical measures from large data of trajectories and discuss the potential of experimental settings embedding controlled perturbations to probe response in migratory behavior.

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Section: What Can Biophysical Modeling Contribute To Understanding Mo...mentioning

confidence: 99%

Section: What Can Biophysical Modeling Contribute To Understanding Mo...mentioning

confidence: 99%

Mesenchymal cell migration on one-dimensional micropatterns

Heyn,

Rädler,

Falcke

2024

Front. Cell Dev. Biol.

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“…Confined spaces or printed structures can lead to cell alignment or induce changes within cells leading for example to stem cell differentiation into certain cell types. [86,195,[203][204][205][206][207] For a detailed overview and analysis of these effects on single cells, we kindly refer to a recent review on this topic by Link et al [208] Recently, the investigation of single cells in dynamic environments has become possible by employing printable materials, whose properties can be changed on demand upon external stimuli. One of the first examples of such a material was presented by Hippler et al in 2020 (see Figure 7B).…”

Section: Cell Scaffoldsmentioning

confidence: 99%

“…[ 86,195,203–207 ] For a detailed overview and analysis of these effects on single cells, we kindly refer to a recent review on this topic by Link et al. [ 208 ]…”

Section: Life Sciencesmentioning

confidence: 99%

Recent Advances in Multi‐Photon 3D Laser Printing: Active Materials and Applications

Mainik,

Spiegel,

Blasco

2023

Advanced Materials

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Since the pioneering work of Kawata and colleagues in 1997, multi‐photon 3D laser printing, also known as direct laser writing, has made significant advancements in a wide range of fields. Moreover, the development and commercialization of photocurable inks for this technique have expanded rapidly. One of the current trends is the transition from static to active printable materials, often referred to as 4D microprinting, which enables a new degree of control in the printed systems. This review focuses on four primary application areas: microrobotics, optics and photonics, microfluidics, and life sciences, highlighting recent progress and the crucial role of active materials, including liquid crystalline elastomers, hydrogels, shape memory polymers, and composites, among others. It also addresses ongoing challenges and provides insights into the future prospects in the different fields.

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“…Mathematical modelling plays an important role in improving and validating our understanding of cell shape, especially if combined with quantitative experiments. Simulating cell shape in structured environments tests and increases our understanding of the underlying mechanisms governing cell behavior [ 16 ]. Analytical 2D cell shape models have been developed to predict cell shape on micropatterned environments using line and surface tensions [ 17 , 18 ], and the notion that the contractile actin cortex is responsible for 3D cell shape is wide-spread [ 19 , 20 ].…”

Section: Introductionmentioning

confidence: 99%

Modelling cell shape in 3D structured environments: A quantitative comparison with experiments

Link,

Jaggy,

Bastmeyer

et al. 2024

PLoS Comput Biol

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Cell shape plays a fundamental role in many biological processes, including adhesion, migration, division and development, but it is not clear which shape model best predicts three-dimensional cell shape in structured environments. Here, we compare different modelling approaches with experimental data. The shapes of single mesenchymal cells cultured in custom-made 3D scaffolds were compared by a Fourier method with surfaces that minimize area under the given adhesion and volume constraints. For the minimized surface model, we found marked differences to the experimentally observed cell shapes, which necessitated the use of more advanced shape models. We used different variants of the cellular Potts model, which effectively includes both surface and bulk contributions. The simulations revealed that the Hamiltonian with linear area energy outperformed the elastic area constraint in accurately modelling the 3D shapes of cells in structured environments. Explicit modelling the nucleus did not improve the accuracy of the simulated cell shapes. Overall, our work identifies effective methods for accurately modelling cellular shapes in complex environments.

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Cell Shape and Forces in Elastic and Structured Environments: From Single Cells to Organoids

Cited by 7 publications

References 329 publications

Mesenchymal cell migration on one-dimensional micropatterns

Mesenchymal cell migration on one-dimensional micropatterns

Recent Advances in Multi‐Photon 3D Laser Printing: Active Materials and Applications

Modelling cell shape in 3D structured environments: A quantitative comparison with experiments

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