Reversible signal transmission in an active mechanical metamaterial

Browning, Alexander P; Woodhouse, Francis G.; Simpson, Matthew J.

doi:10.1098/rspa.2019.0146

Cited by 14 publications

(8 citation statements)

References 48 publications

(145 reference statements)

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“…By taking a small time interval Δ t , the effective displacement of the ith point is where μ is the damping constant. This formulation is readily used in other ABM settings, for example see Murray et al (2012); Murphy et al (2019); Browning et al (2019).…”

Section: Methodsmentioning

confidence: 99%

Calibration of Agent Based Models for Monophasic and Biphasic Tumour Growth using Approximate Bayesian Computation

Wang

Drovandi

Jenner

et al. 2022

Preprint

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Agent-based models (ABMs) are readily used to capture the stochasticity in tumour evolution; however, these models can pose a challenge in terms of their ability to be validated with experimental measurements. The Voronoi cell-based model (VCBM) is an off-lattice agent-based model that captures individual cell shapes using a Voronoi tessellation and mimics the evolution of cancer cell proliferation and movement. The ability of this type of model to capture tumour growth accurately remains unknown. In this paper, a likelihood-free method is employed to calibrate a VCBM to breast, ovarian and pancreatic cancer measurements in vivo. Our approach involves estimating the distribution of parameters that govern cancer cell proliferation and recovering the output from the model based on estimated parameters so that the outputs match the experimental data. Our results show that the VCBM can accurately model monophasic tumour growth but lacks the ability to capture biphasic or multiphasic tumour growth. Furthermore, we find that the time taken for a daughter cell to become a mature adult cell is highly informed by the data. Moving forward, this allows us to propose future refinements to the model to improve accuracy, whilst also making conclusions about the differences in cancer cell characteristics.

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Section: Methodsmentioning

confidence: 99%

Calibration of Agent Based Models for Monophasic and Biphasic Tumour Growth using Approximate Bayesian Computation

Wang

Drovandi

Jenner

et al. 2022

Preprint

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“…However, the end of the 1D cell x N (t) may change relative to the origin as the tissue is stretched. [5] For i = 1, we may have the clamped (fixed boundary) or free (zero force, T j = 0 where j is a fictitious external cell) boundary conditions. Using (2.2), we have the equations:…”

Section: Tissue Modelmentioning

confidence: 99%

“…Traditionally, these models rely on the concept of Hooke’s law and use Newton’s laws of motion, along with overdamped motion, to lead to a force balance, resulting in a simple linear spring interaction between cells with a single fixed point [9, 16, 19]. However, there has been recent work to model bistable springs to describe the mechanical transfer of information [5, 15].…”

Section: Introductionmentioning

confidence: 99%

Active Remodelling of Tissues to Describe Biphasic Rheological Responses

GERMANO,

KHUU,

JENNER

et al. 2023

ANZIAM J.

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Tissues form from collections of cells that interact together mechanically via cell-to-cell adhesion, mediated by transmembrane cell adhesion molecules. Under a sufficiently large amount of induced stress, these tissues can undergo elastic deformation in the direction of tension, where they then elongate without any topological changes, and experience plastic deformation within the tissue. In this work, we present a novel mathematical model describing the deformation of cells, where tissues are elongated in a controlled manner. In doing so, the cells are able to undergo remodelling through elastic and then plastic deformation, in accordance with experimental observation. Our model describes bistable sizes of a cell that actively deform under stress to elongate the cell. In the absence of remodelling, the model reduces to the standard linear interaction model. In the presence of instant remodelling, we provide a bifurcation analysis to describe the existence of the bistable cell sizes. In the case of general remodelling, we show numerically that cells within a tissue may populate both the initial and elongated cell sizes, following a sufficiently large degree of stress.

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“…By providing local energy minima in the structural configuration space, such bistable elements allow metamaterials to carry mechanical loads, locally store elastic energy in the structure and/or generate multiple stable reconfigurable geometries. [16,17] These functionalities have been harnessed to design deployable structures, [18,19] impact absorbers, [20][21][22] robotic actuators, [23,24] energy harvesting, [25,26] and micromechanical systems, [27,28] waveguiding systems, [29][30][31] memory [32,33] and logic devices, [34][35][36][37] and morphing elements in architecture. In particular, multistability in metamaterials allows for programming both static and dynamic properties, such as stiffness adaptation, [6,38] tunable bandgaps, [39,40] and quantum valley Hall effect.…”

Section: Introductionmentioning

confidence: 99%

Dome‐Patterned Metamaterial Sheets

et al. 2020

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The properties of conventional materials result from the arrangement of and the interaction between atoms at the nanoscale. Metamaterials have shifted this paradigm by offering property control through structural design at the mesoscale, thus broadening the design space beyond the limits of traditional materials. A family of mechanical metamaterials consisting of soft sheets featuring a patterned array of reconfigurable bistable domes is reported here. The domes in this metamaterial architecture can be reversibly inverted at the local scale to generate programmable multistable shapes and tunable mechanical responses at the global scale. By 3D printing a robotic gripper with energy-storing skin and a structure that can memorize and compute spatially-distributed mechanical signals, it is shown that these metamaterials are an attractive platform for novel mechanologic concepts and open new design opportunities for structures used in robotics, architecture, and biomedical applications.

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Reversible signal transmission in an active mechanical metamaterial

Cited by 14 publications

References 48 publications

Calibration of Agent Based Models for Monophasic and Biphasic Tumour Growth using Approximate Bayesian Computation

Calibration of Agent Based Models for Monophasic and Biphasic Tumour Growth using Approximate Bayesian Computation

Active Remodelling of Tissues to Describe Biphasic Rheological Responses

Dome‐Patterned Metamaterial Sheets

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