Modelling of the Soft Shell Technique Using Computational Fluid Dynamics.

Clinical ophthalmology (Auckland, N.Z.) Pub Date : 2025-04-28 eCollection Date: 2025-01-01 DOI:10.2147/OPTH.S520105

Ippei Watanabe, Hirokazu Mukuno

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引用次数: 0

Abstract

Purpose: To clarify how ophthalmic viscosurgical devices (OVDs) behave during the soft shell technique.

Methods: We simulated the fluids dynamics of a Dispersive-OVD [Combination of 3% hyaluronic acid (HA) and 4% chondroitin sulfate] and Cohesive-OVD (1% HA with a high molecular weight) during the soft shell technique using the software program Fluent2023R2 and ICEM CFD. During the simulation, 0.1 mL of Dispersive-OVD was injected into the eye model for 9 sec, followed by 0.1 mL of Cohesive-OVD for 5 sec. The mass fraction, static pressure, velocity, shear rate and apparent viscosity of each OVD were evaluated during intraocular injection.

Results: Initially, the Dispersive-OVD was injected upward into the anterior chamber. Although the pressure applied to the cannula tip during injection was high, almost no pressure rise occurred inside the eye. Subsequently, injection of Cohesive-OVD pushed the Dispersive-OVD up, forming a thin layer of Dispersive-OVD covering the entire corneal endothelium. Injection of Cohesive-OVD increased the velocity magnitude towards the eye incision; once the OVD filled the eye, it overflowed from the incision. The shear rate of Cohesive-OVD was higher than that of Dispersive-OVD when injected through the cannula lumen and out of the tip. Therefore, the apparent viscosity of Cohesive-OVD near the cannula tip was about one-third lower than that of Dispersive-OVD. The shear rate of the Dispersive-OVD at the corneal endothelial surface during Cohesive-OVD injection was less than 10^-1-10 s^-1, and the apparent viscosity was less than 30-100 Pa∙s.

Conclusion: Fluid dynamics simulation demonstrated how the soft shell technique works using two agents with different physical properties. The parameters obtained in this study provide useful metrics for understanding and predicting OVD behavior during eye surgery.

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软壳技术的计算流体力学建模。

目的：探讨眼粘手术装置（ovd）在软壳技术中的作用。方法：利用Fluent2023R2软件和ICEM CFD软件，模拟了分散型- ovd[3%透明质酸（HA）和4%硫酸软骨素的组合]和内聚型- ovd（1%高分子量HA）在软壳技术中的流体动力学。模拟过程中，先向眼模型内注射0.1 mL弥散性OVD，持续9秒，再注射0.1 mL内聚性OVD，持续5秒。眼内注射时评估各OVD的质量分数、静压、速度、剪切速率和表观粘度。结果：开始时，分散- ovd向上注入前房。虽然注射时施加在套管尖端的压力很高，但眼内几乎没有压力升高。随后，注射内聚性ovd将弥散性ovd向上推，形成覆盖整个角膜内皮的薄层弥散性ovd。注射内聚物- ovd增加了眼切口方向的速度幅度；一旦OVD填满眼睛，它就会从切口溢出。内聚性ovd的剪切速率高于弥散性ovd。因此，内聚性ovd在套管尖端附近的表观粘度比弥散性ovd低约1 / 3。在注射过程中，分散型ovd在角膜内皮表面的剪切速率小于10-1-10 s-1，表观粘度小于30-100 Pa∙s。结论：流体动力学模拟演示了软壳技术如何使用两种具有不同物理性质的介质。本研究中获得的参数为理解和预测眼科手术期间的OVD行为提供了有用的指标。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Clinical ophthalmology (Auckland, N.Z.)

CiteScore

4.10

自引率

0.00%

发文量