The image-based ultrasonic cell shaking test
The image-based ultrasonic cell shaking test
Mechanical signals play a vital role in cell biology and is a vast area of research. Thus, there is motivation to understand cell deformation and mechanobiological responses. However, the ability to controllably deform cells in the ultrasonic regime and test their response is a noted challenge throughout the literature. Quantifying and eliciting an appropriate stimulus has proven to be difficult, resulting in methods that are either too aggressive or oversimplified. Furthermore, the ability to gain a real-time insight into cell deformation and link this with the biological response is yet to be achieved. One application of this understanding is in ultrasonic surgical cutting, which is a promising alternative to traditional methods, but with little understanding of its effect on cells. Here we present the image based ultrasonic cell shaking test, a novel method that enables controllable loading of cells and quantification of their response to ultrasonic vibrations. Practically, this involves seeding cells on a substrate that resonates at ultrasonic frequencies and transfers the deformation to the cells. This is then incorporated into microscopic imaging techniques to obtain high-speed images of ultrasonic cell deformation that can be analysed using digital image correlation techniques. Cells can then be extracted after excitation to undergo analysis to understand the biological response to the deformation. This method could aid in understanding the effects of ultrasonic stimulation on cells and how activated mechanobiological pathways result in physical and biochemical responses.
Aggression, Biophysics, Motivation, Ultrasonic Waves, Ultrasonics
e0285906
Ballard, Miranda
eb1c6f0c-67bc-41cc-8d29-da6c5287c4a9
Marek, Aleksander
6d758ff6-6423-462d-88e9-d44e71df4c3d
Pierron, Fabrice
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
Chanda, Souptick
1c1c7ce1-3c73-46a2-9398-3d99be522836
15 September 2023
Ballard, Miranda
eb1c6f0c-67bc-41cc-8d29-da6c5287c4a9
Marek, Aleksander
6d758ff6-6423-462d-88e9-d44e71df4c3d
Pierron, Fabrice
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
Chanda, Souptick
1c1c7ce1-3c73-46a2-9398-3d99be522836
Ballard, Miranda, Marek, Aleksander and Pierron, Fabrice
,
Chanda, Souptick
(ed.)
(2023)
The image-based ultrasonic cell shaking test.
PLoS ONE, 18 (9 SEPTEMBER), , [e0285906].
(doi:10.1371/journal.pone.0285906).
Abstract
Mechanical signals play a vital role in cell biology and is a vast area of research. Thus, there is motivation to understand cell deformation and mechanobiological responses. However, the ability to controllably deform cells in the ultrasonic regime and test their response is a noted challenge throughout the literature. Quantifying and eliciting an appropriate stimulus has proven to be difficult, resulting in methods that are either too aggressive or oversimplified. Furthermore, the ability to gain a real-time insight into cell deformation and link this with the biological response is yet to be achieved. One application of this understanding is in ultrasonic surgical cutting, which is a promising alternative to traditional methods, but with little understanding of its effect on cells. Here we present the image based ultrasonic cell shaking test, a novel method that enables controllable loading of cells and quantification of their response to ultrasonic vibrations. Practically, this involves seeding cells on a substrate that resonates at ultrasonic frequencies and transfers the deformation to the cells. This is then incorporated into microscopic imaging techniques to obtain high-speed images of ultrasonic cell deformation that can be analysed using digital image correlation techniques. Cells can then be extracted after excitation to undergo analysis to understand the biological response to the deformation. This method could aid in understanding the effects of ultrasonic stimulation on cells and how activated mechanobiological pathways result in physical and biochemical responses.
Text
journal.pone.0285906
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Accepted/In Press date: 5 September 2023
Published date: 15 September 2023
Additional Information:
Funding Information:
Funding: This work is funded by the Engineering and Physical Sciences Research Council and part of the Ultrasurge Project under Grant EP/R045291/ 1. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. https://gow.epsrc. ukri.org/NGBOViewGrant.aspx?GrantRef=EP/ R045291/1.
Publisher Copyright:
Copyright: © 2023 Ballard et al.
Keywords:
Aggression, Biophysics, Motivation, Ultrasonic Waves, Ultrasonics
Identifiers
Local EPrints ID: 482266
URI: http://eprints.soton.ac.uk/id/eprint/482266
ISSN: 1932-6203
PURE UUID: bf44463e-6694-46a3-9b89-47f16d0b405c
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Date deposited: 22 Sep 2023 16:42
Last modified: 18 Mar 2024 03:59
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Contributors
Author:
Miranda Ballard
Author:
Aleksander Marek
Editor:
Souptick Chanda
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