Image-based evaluation of cutting forces during ultrasonic cutting of bone
Image-based evaluation of cutting forces during ultrasonic cutting of bone
Background: ultrasonic surgical cutting tools are an appealing alternative to traditional devices. The measurement of time-resolved ultrasonic cutting forces is important to understand the material removal process but a challenge because of inertial effects affecting the results of traditional load cells.
Objective: the present work details an attempt to resolve the cutting force of an ultrasonically powered surgical tool at the time scale of the 25 kHz ultrasonic excitation, by using the tool tip itself as the load cell.
Methods: ultra-high speed imaging is used in conjunction with Digital Image Correlation to measure strain and acceleration in the cutting blade. Dynamic equilibrium is then leveraged to identify the cutting force at the tool tip within a single cutting cycle of the tool. The methodology is first verified on simulated data before being applied to experiments on cortical bovine bone (free vibrations and cutting).
Results: the force detection threshold was evaluated on the order of 5 N, recorded at 1 Mfps with a Shimadzu HPV-X camera. A particular difficulty was that the blade exhibited some out-of-plane bending which created a bias on the identified cutting force. Finally, it was possible to detect that when the blade engaged in the workpiece, a compressive force acted on the tool while during the disengagement part of the cycle, the force was null.
Conclusions: it was shown that it was possible to use the thin flat blade of an in-house developed ultrasonic surgical tool to measure time-resolved cutting forces.
Marek, A.
6d758ff6-6423-462d-88e9-d44e71df4c3d
Li, X.
ed01c0d5-68e0-4abe-8642-5b9ebf153314
Lucas, M.
b2f7b99f-25f8-41a1-ae97-4ff46f4c21a5
Pierron, F.
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
9 December 2025
Marek, A.
6d758ff6-6423-462d-88e9-d44e71df4c3d
Li, X.
ed01c0d5-68e0-4abe-8642-5b9ebf153314
Lucas, M.
b2f7b99f-25f8-41a1-ae97-4ff46f4c21a5
Pierron, F.
a1fb4a70-6f34-4625-bc23-fcb6996b79b4
Marek, A., Li, X., Lucas, M. and Pierron, F.
(2025)
Image-based evaluation of cutting forces during ultrasonic cutting of bone.
Experimental Mechanics.
(doi:10.1007/s11340-025-01256-0).
Abstract
Background: ultrasonic surgical cutting tools are an appealing alternative to traditional devices. The measurement of time-resolved ultrasonic cutting forces is important to understand the material removal process but a challenge because of inertial effects affecting the results of traditional load cells.
Objective: the present work details an attempt to resolve the cutting force of an ultrasonically powered surgical tool at the time scale of the 25 kHz ultrasonic excitation, by using the tool tip itself as the load cell.
Methods: ultra-high speed imaging is used in conjunction with Digital Image Correlation to measure strain and acceleration in the cutting blade. Dynamic equilibrium is then leveraged to identify the cutting force at the tool tip within a single cutting cycle of the tool. The methodology is first verified on simulated data before being applied to experiments on cortical bovine bone (free vibrations and cutting).
Results: the force detection threshold was evaluated on the order of 5 N, recorded at 1 Mfps with a Shimadzu HPV-X camera. A particular difficulty was that the blade exhibited some out-of-plane bending which created a bias on the identified cutting force. Finally, it was possible to detect that when the blade engaged in the workpiece, a compressive force acted on the tool while during the disengagement part of the cycle, the force was null.
Conclusions: it was shown that it was possible to use the thin flat blade of an in-house developed ultrasonic surgical tool to measure time-resolved cutting forces.
Text
s11340-025-01256-0
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More information
Accepted/In Press date: 21 November 2025
e-pub ahead of print date: 9 December 2025
Published date: 9 December 2025
Identifiers
Local EPrints ID: 507438
URI: http://eprints.soton.ac.uk/id/eprint/507438
ISSN: 1741-2765
PURE UUID: 0eec6ee8-5d49-4699-8285-74a4b8dfffa4
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Date deposited: 09 Dec 2025 17:45
Last modified: 10 Dec 2025 03:09
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Author:
A. Marek
Author:
X. Li
Author:
M. Lucas
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