Mechanical stimulation devices for mechanobiology studies: a market, literature, and patents review

Melo-Fonseca, F.; Carvalho, Ó.; Gasik, Michael; Miranda, G.; Silva, Filipe

doi:10.1007/s42242-023-00232-8

Cited by 6 publications

(8 citation statements)

References 100 publications

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“…59 As cells experienced about 10% mechanical deformation through the scaffold during contraction and expansion cycles, the deformation of the polyHIPE/PEDOT scaffold and the induced cell response are in the same range of 2.5−24% deformation as in various studies describing the application of external tensile and compressive forces or shear stress. 1,62 Compared to other dynamic systems such as deformable substrates, 63,64 electronic patches, 65 or commercial devices such as Flexcell 66 or MechanoCulture, 67 which permit uniaxial deformation, the motion of the polyHIPE/PEDOT scaffold is multiaxial. It confers on the 3D porous polyHIPE/PEDOT scaffolds a full 4D dynamic and reversible microenvironment for cell culture.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…In vivo , cells reside in a complex and dynamic 3D microenvironment, providing both structural and functional support. , The cell microenvironment includes a wide variety of biochemical and biophysical cues that orchestrate cell adhesion, proliferation, differentiation, and migration . In turn, the properties of the cell microenvironment constantly change under the influence of cells.…”

Section: Introductionmentioning

confidence: 99%

“…16 In a constant effort to better mimic the cell environment in vitro, mechanical stimulation devices were introduced within 3D scaffolds to stimulate cells through deformation of the material. 1,22 Compression, tension, or shear stresses trigger mechanotransduction within cells, a process in which the mechanical input is converted into a biological response. Nevertheless, most of these devices rely on applying external deformations to passive scaffolds and they fail to properly mimic the dynamic properties of the in vivo environment.…”

Section: ■ Introductionmentioning

confidence: 99%

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Electroactive 4D Porous Scaffold Based on Conducting Polymer as a Responsive and Dynamic In Vitro Cell Culture Platform

Hahn,

Ferrandez-Montero,

Queri

et al. 2024

ACS Appl. Mater. Interfaces

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In vivo, cells reside in a 3D porous and dynamic microenvironment. It provides biochemical and biophysical cues that regulate cell behavior in physiological and pathological processes. In the context of fundamental cell biology research, tissue engineering, and cell-based drug screening systems, a challenge is to develop relevant in vitro models that could integrate the dynamic properties of the cell microenvironment. Taking advantage of the promising high internal phase emulsion templating, we here designed a polyHIPE scaffold with a wide interconnected porosity and functionalized its internal 3D surface with a thin layer of electroactive conducting polymer poly(3,4ethylenedioxythiophene) (PEDOT) to turn it into a 4D electroresponsive scaffold. The resulting scaffold was cytocompatible with fibroblasts, supported cellular infiltration, and hosted cells, which display a 3D spreading morphology. It demonstrated robust actuation in ion-and protein-rich complex culture media, and its electroresponsiveness was not altered by fibroblast colonization. Thanks to customized electrochemical stimulation setups, the electromechanical response of the polyHIPE/PEDOT scaffolds was characterized in situ under a confocal microscope and showed 10% reversible volume variations. Finally, the setups were used to monitor in real time and in situ fibroblasts cultured into the polyHIPE/PEDOT scaffold during several cycles of electromechanical stimuli. Thus, we demonstrated the proof of concept of this tunable scaffold as a tool for future 4D cell culture and mechanobiology studies.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Electroactive 4D Porous Scaffold Based on Conducting Polymer as a Responsive and Dynamic In Vitro Cell Culture Platform

Hahn,

Ferrandez-Montero,

Queri

et al. 2024

ACS Appl. Mater. Interfaces

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“…One of the simplest and earliest mechanical actuation platforms among them are uniaxial mechanical stretching devices, where a substrate is attached on one side to a fixed clamp and a moving clamp on its other side is uniaxially stretched using an attrition strategy; it can either be manual or can be motor controlled . Motor-controlled devices gained popularity in the development of such devices because of their precision and repeatability.…”

Section: Introductionmentioning

confidence: 99%

“…3 One of the simplest and earliest mechanical actuation platforms among them are uniaxial mechanical stretching devices, where a substrate is attached on one side to a fixed clamp and a moving clamp on its other side is uniaxially stretched using an attrition strategy; it can either be manual or can be motor controlled. 4 Motor-controlled devices gained popularity in the development of such devices because of their precision and repeatability. Many commercially available sources provided such mechanical attrition platforms, including Cell Stretching Bioreactors from Flexcell International, 5 C Stretch systems from IonOptrix, 6 Biomatrix stretcher, 7 and many more.…”

Section: Introductionmentioning

confidence: 99%

Unveiling Mechanobiology: A Compact Device for Uniaxial Mechanical Stimulation on Nanofiber Substrates and Its Impact on Cellular Behavior and Nanoparticle Distribution

Basak,

Tiwari,

Sharma

et al. 2024

ACS Appl. Bio Mater.

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Biotechnology and its allied sectors, such as tissue culture, regenerative medicine, and personalized medicine, primarily rely upon extensive studies on cellular behavior and their molecular pathways for generating essential knowledge and innovative strategies for human survival. Most such studies are performed on flat, adherent, plastic-based surfaces and use nanofiber and hydrogellike soft matrices from the past few decades. However, such static culture conditions cannot mimic the immediate cellular microenvironment, where they perceive or generate a myriad of different mechanical forces that substantially affect their downstream molecular pathways. Including such mechanical forces, still limited to specialized laboratories, using a few commercially available or noncommercial technologies are gathering increasing attention worldwide. However, large-scale consideration and adaptation by developing nations have yet to be achieved due to the lack of a cost-effective, reliable, and accessible solution. Moreover, investigations on cellular response upon uniaxial mechanical stretch cycles under more in vivo mimetic conditions are yet to be studied comprehensively. In order to tackle these obstacles, we have prepared a compact, 3D-printed device using a microcontroller, batteries, sensors, and a stepper motor assembly that operates wirelessly and provides cyclic mechanical attrition to any thin substrate. We have fabricated water-stable and stretchable nanofiber substrates with different fiber orientations by using the electrospinning technique to investigate the impact of mechanical stretch cycles on the morphology and orientation of C2C12 myoblast-like cells. Additionally, we have examined the uptake and distribution properties of BSA-epirubicin nanoparticles within cells under mechanical stimulation, which could act as fluorescently active drug-delivery agents for future therapeutic applications. Consequently, our research offers a comprehensive analysis of cellular behavior when cells are subjected to uniaxial stretching on various nanofiber mat architectures. Furthermore, we present a cost-effective alternative solution that addresses the long-standing requirement for a compact, user-friendly, and tunable device, enabling more insightful outcomes in mechanobiology.

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Engineering placental trophoblast fusion: A potential role for biomechanics in syncytialization

Parameshwar,

Vaillancourt,

Moraes

2024

Placenta

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Mechanical stimulation devices for mechanobiology studies: a market, literature, and patents review

Cited by 6 publications

References 100 publications

Electroactive 4D Porous Scaffold Based on Conducting Polymer as a Responsive and Dynamic In Vitro Cell Culture Platform

Electroactive 4D Porous Scaffold Based on Conducting Polymer as a Responsive and Dynamic In Vitro Cell Culture Platform

Unveiling Mechanobiology: A Compact Device for Uniaxial Mechanical Stimulation on Nanofiber Substrates and Its Impact on Cellular Behavior and Nanoparticle Distribution

Engineering placental trophoblast fusion: A potential role for biomechanics in syncytialization

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