Yonghang Jiang scite author profile

Yonghang Jiang

5Publications

8Citation Statements Received

61Citation Statements Given

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123

Affiliations

University of Strathclyde, Shandong University

Publications

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Influence of a Biocompatible Hydrophilic Needle Surface Coating on a Puncture Biopsy Process for Biomedical Applications

et al. 2020

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A puncture biopsy is a widely used, minimally invasive surgery process. During the needle insertion process, the needle body is always in direct contact with a biological soft tissue. Tissue adhesion and different degrees of tissue damage occur frequently. Optimization of the needle surface, and especially the lubrication of the needle surface, can deal with these problems efficiently. Therefore, in this paper, a biocompatible hydrophilic coating was applied onto the surface of a needle to improve the surface quality of the needle surface. Further, a simplified finite element model of insertion was established, and extracorporeal insertion experiments were used to verify the accuracy of the model. Then, by analyzing a simulation model of a coated needle and a conventional needle, the influence of the application of the coated needle on the insertion process was obtained. It can be seen from the results that the coating application relieved the force on the needle and the soft tissue during the insertion process and could significantly reduce friction during the insertion process. At the same time, the deformation of biological soft tissue was reduced, and the adhesion situation between the needle and tissue improved, which optimized the puncture needle.

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Needle deformation in the process of puncture surgery: experiment and simulation

et al. 2020

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Three-dimensional Modeling and Simulation of Muscle Tissue Puncture Process

Song

Gao

et al. 2022

Chin. J. Mech. Eng.

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Needle biopsy is an essential part of modern clinical medicine. The puncture accuracy and sampling success rate of puncture surgery can be effectively improved through virtual surgery. There are few three-dimensional puncture (3D) models, which have little significance for surgical guidance under complicated conditions and restrict the development of virtual surgery. In this paper, a 3D simulation of the muscle tissue puncture process is studied. Firstly, the mechanical properties of muscle tissue are measured. The Mooney-Rivlin (M-R) model is selected by considering the fitting accuracy and calculation speed. Subsequently, an accurate 3D dynamic puncture model is established. The failure criterion is used to define the breaking characteristics of the muscle, and the bilinear cohesion model defines the breaking process. Experiments with different puncture speeds are carried out through the built in vitro puncture platform. The experimental results are compared with the simulation results. The experimental and simulated reaction force curves are highly consistent, which verifies the accuracy of the model. Finally, the model under different parameters is studied. The simulation results of varying puncture depths and puncture speeds are analyzed. The 3D puncture model can provide more accurate model support for virtual surgery and help improve the success rate of puncture surgery.

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3D Cohesive Finite Element Minimum Invasive Surgery Simulation Based on Kelvin-Voigt Model

Jiang

Song

Luo

2022

Chin. J. Mech. Eng.

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Minimally invasive surgery is an important technique used for cytopathological examination. Recently, multiple studies have been conducted on a three-dimensional (3D) puncture simulation model as it can reveal the internal deformation state of the tissue at the micro level. In this study, a viscoelastic constitutive equation suitable for muscle tissue was derived. Additionally, a method was developed to define the fracture characteristics of muscle tissue material during the simulation process. The fracture of the muscle tissue in contact with the puncture needle was simulated using the cohesive zone model and a 3D puncture finite element model was established to analyze the deformation of the muscle tissue. The stress nephogram and reaction force under different parameters were compared and analyzed to study the deformation of the biological soft tissue and guide the actual operation process and reduce pain.

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3D Cohesive Finite Element Minimum Invasive Surgery Simulation Based on Kelvin Voigt Model

Jiang

Song

Luo

2021

Preprint

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Minimum Invasive Surgery is an important means of cytopathological examination. At present, there are few researches on three dimensional (3D) puncture simulation model base on suitable constitutive model, so a reasonable three dimensional puncture simulation model can reveal the internal deformation state of the tissue at the micro level. In this paper, a new viscoelastic constitutive equation suitable for muscle tissue and a method to define the fracture characteristics of muscle tissue material in the simulation process are proposed. The fracture of muscle tissue in contact with puncture needle is simulated by using the cohesive zone model, and a 3D puncture finite element model is established to analyze the deformation of muscle tissue. The stress nephogram and reaction force under different parameters were compared and analyzed to study the deformation of biological soft tissue, so as to guide the actual operation process and reduce pain.

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Yonghang Jiang

Influence of a Biocompatible Hydrophilic Needle Surface Coating on a Puncture Biopsy Process for Biomedical Applications

Needle deformation in the process of puncture surgery: experiment and simulation

Three-dimensional Modeling and Simulation of Muscle Tissue Puncture Process

3D Cohesive Finite Element Minimum Invasive Surgery Simulation Based on Kelvin-Voigt Model

3D Cohesive Finite Element Minimum Invasive Surgery Simulation Based on Kelvin Voigt Model

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