In vivo video microscopy of the rupturing process of thin blood vessels to clarify the mechanism of bruising caused by blunt impact: an animal study

The thresholds of mechanical inputs for bruising caused by blunt impact are important in the fields of machine safety and forensics. However, reliable data on these thresholds remain inadequate owing to a lack of in vivo experiments, which are crucial for investigating the occurrence of bruising. Si...

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Bibliographic Details
Published in:Biomedical engineering online 2024-09, Vol.23 (1), p.94-13, Article 94
Main Authors: Fujikawa, Tatsuo, Yamada, Yoji
Format: Article
Language:English
Subjects:
Analysis
Animals
Biomechanical Phenomena
Blood vessels
Blood Vessels - diagnostic imaging
Blunt trauma
Bruising
Care and treatment
Contact force
Contusions
Contusions - etiology
Deformation
Development and progression
Experiments
Finite Element Analysis
Finite element method
Fish
Fishes
Forensic sciences
Forensics
Impact analysis
In vivo methods and tests
Injuries
Internal bleeding
Mechanical Phenomena
Mechanical properties
Methods
Microscope and microscopy
Microscopy
Microscopy, Video
Non-accidental injuries
Rupturing
Safety of machinery
Simulation
Simulation methods
Soft tissue injury
Soft tissues
Thresholds
Transparent glass catfish
Video compression
Viscosity
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Summary:The thresholds of mechanical inputs for bruising caused by blunt impact are important in the fields of machine safety and forensics. However, reliable data on these thresholds remain inadequate owing to a lack of in vivo experiments, which are crucial for investigating the occurrence of bruising. Since experiments involving live human participants are limited owing to ethical concerns, finite-element method (FEM) simulations of the bruising mechanism should be used to compensate for the lack of experimental data by estimating the thresholds under various conditions, which requires clarifying the mechanism of formation of actual bruises. Therefore, this study aimed to visualize the mechanism underlying the formation of bruises caused by blunt impact to enable FEM simulations to estimate the thresholds of mechanical inputs for bruising. In vivo microscopy of a transparent glass catfish subjected to blunt contact with an indenter was performed. The fish were anesthetized by immersing them in buffered MS-222 (75-100 mg/L) and then fixed on a subject tray. The indenter, made of transparent acrylic and having a rectangular contact area with dimensions of 1.0 mm × 1.5 mm, was loaded onto the lateral side of the caudal region of the fish. Blood vessels and surrounding tissues were examined through the transparent indenter using a microscope equipped with a video camera. The contact force was measured using a force-sensing table. One of the processes of rupturing thin blood vessels, which are an essential component of the bruising mechanism, was observed and recorded as a movie. The soft tissue surrounding the thin blood vessel extended in a plane perpendicular to the compressive contact force. Subsequently, the thin blood vessel was pulled into a straight configuration. Next, it was stretched in the axial direction and finally ruptured. The results obtained indicate that the extension of the surrounding tissue in the direction perpendicular to the contact force as well as the extension of the thin blood vessels are important factors in the bruising mechanism, which must be reproduced by FEM simulation to estimate the thresholds.
ISSN:1475-925X
1475-925X
DOI:10.1186/s12938-024-01284-2