Mechanical Characterization of Brain Tissue in Compression

Shafiee, Abbas; Ahmadian, Mohammad Taghi; Hoviattalab, Maryam

doi:10.1115/detc2016-59019

Cited by 9 publications

(10 citation statements)

References 10 publications

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“…The Gearboxes have three stages and the maximum intermittent torque at gear output is 45 Nm. The ATI Mini45 sensor, which its resolutions are F x , F y = 1 8 N, and capable of measuring 6145N in each direction, is used for sensing the applied force to the robotic system. The sensor is located on the end-effector.…”

Section: The Features Of the Upper Limbs Rehabilitation Robot Systemmentioning

confidence: 99%

“…The body limb disability traumas such as spinal cord injury, brain injury, 1 and stroke can lead to nervous system damages, causing loss of upper, and lower limb disabilities. The traditional rehabilitation training process extensively relies on medical experts' experiences, and it requires physical activity for both the patient and the expert.…”

Section: Introductionmentioning

confidence: 99%

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Nonlinear time delay estimation based model reference adaptive impedance control for an upper-limb human-robot interaction

Omrani

Moghaddam

2021

Proc Inst Mech Eng H

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A nonlinear Time Delay Estimation (TDE) based model reference adaptive impedance controller was developed for Tarbiat Modares University Upper Limbs Rehabilitation Robot (TUERR). The proposed controller uses a stable reference impedance model, which produces desired dynamic relationship between applied force and position error for the robot End-effector to track the desired trajectory. TDE based model reference adaptive controller estimates unknown system dynamics and uncertainties, and the adaption law modifies the controller gains. Using a Lyapunov function was shown trajectory tracking errors in the overall system are bounded. In addition, a performance-based velocity profile proposed to modify the pace of trajectory planning considering the deviation from the desired path. Finally, the performance of the presented controller and rehabilitation process is experimentally investigated for TUERR.

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Section: The Features Of the Upper Limbs Rehabilitation Robot Systemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nonlinear time delay estimation based model reference adaptive impedance control for an upper-limb human-robot interaction

Omrani

Moghaddam

2021

Proc Inst Mech Eng H

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“…This example shows the advantages of Selective S‐FEMs by comparison with newly published papers. Recently, brain tissue using visco‐hyperelastic constitutive model has been researched in many groups, 84‐87 and the corresponding material parameters are listed in Table 3.…”

Section: Numerical Examplesmentioning

confidence: 99%

“…The contact force of the rigid plate calculated by Selective ES/NS‐FEM. Liu et al, 87 shafiee et al 86 and Ho et al 85 [Color figure can be viewed at wileyonlinelibrary.com]…”

Section: Numerical Examplesmentioning

confidence: 99%

A selective smoothed finite element method with visco‐hyperelastic constitutive model for analysis of biomechanical responses of brain tissues

Jiang

et al. 2020

Numerical Meth Engineering

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Brain tissues are known for exhibiting complex nonlinear and time-dependent properties, which require visco-hyperelastic constitutive models for proper simulation. In this paper, a Total Lagrangian Explicit Selective Smoothed Finite Element Method (Selective S-FEM) is formulated to analyze the dynamic behavior of incompressible brain tissues undergoing extremely large deformation. The proposed Selective S-FEM deals with three-dimensional problems using four-node tetrahedron elements that can be automatically generated for geometrically complex soft tissues. It consists of the three key ingredients. (i) A visco-hyperelastic constitutive model is developed within the framework of S-FEM in the first time, allowing adequate modeling of the dynamic brain tissue behavior. (ii) Selective S-FEM strategy is used for overcome the mesh distortion and the volumetric locking that often occurs in soft tissues. (iii) Total Lagrangian formulation is used in an explicit algorithm allowing rigorous simulation of extreme large deformation. (iv) A combined implementation of Selective S-FEM with the visco-hyperelastic constitutive model for dynamic simulations. The shear deformation is calculated by Face/Edge-based S-FEM, and the volume deformation is calculated by NS-FEM. Numerical experiments show that Selective S-FEM is a robust solver with good accuracy, and excellent ability to reduce element distortion effects in simulate time-dependence behavior of bio-tissues.

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“…Figure16. The effect of decreasing the hinge's thickness in the y-direction on the mechanical cross-coupling effect (comparison between Case 1 and 7).…”

mentioning

confidence: 99%

A Parametric Study of Mechanical Cross-Coupling in Parallel-Kinematics Piezo-Flexural Nano-Positioning Systems

Shafiee¹,

Ahmadian²,

Akbari³

2021

OJAppS

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Piezo-electric nano-positioning stages are being widely used in applications in which precision and accuracy in the order of nano, and high scanning speeds are paramount. This paper presents a Finite Element Analysis (FEA) of the parallel piezo-flexural nano-positioning (PPNP) stages to investigate motion interference between their different axes. Cross-coupling is one of the significant contributors to undesirable runouts in the precision positioning of PPNP actuators. Using ABAQUS/CAE 2018 software, a 3D model of a PPNP stage was developed. The model consists of a central elastic body connected to a fixed frame through four flexural hinges. A cylindrical stack of multiple piezoelectric disks is placed between the moving central body and the fixed frame. Extensive simulations were carried out for three different friction coefficients in the piezoelectric disks' contact surfaces, different frame materials, and different geometrical configurations of the stage and the hinges. As a result, it was observed that the primary root cause of the mechanical crosscoupling effect could be realized in the combination of the slip and rotation of the piezoelectric disks due to their frictional behavior with the stage moving in the tangential direction, concurrent with changes in the geometry of the stage.

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Mechanical Characterization of Brain Tissue in Compression

Cited by 9 publications

References 10 publications

Nonlinear time delay estimation based model reference adaptive impedance control for an upper-limb human-robot interaction

Nonlinear time delay estimation based model reference adaptive impedance control for an upper-limb human-robot interaction

A selective smoothed finite element method with visco‐hyperelastic constitutive model for analysis of biomechanical responses of brain tissues

A Parametric Study of Mechanical Cross-Coupling in Parallel-Kinematics Piezo-Flexural Nano-Positioning Systems

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