Pu Yutian, Liu Ziyuan, Ye Lin, Xia Yunxin, Chen Xiaoyong, Wang Kehao, Pierscionek Barbara K
Key Laboratory for Biomechanics and Mechanobiology of Ministry for Education, Beijing Advanced Innovation Center for Biomedical Engineering, School of Engineering Medicine and School of Biological Science and Medical Engineering, Beihang University, Beijing, China.
Department of Ophthalmology, Beijing Key Laboratory of Restoration of Damaged Ocular Nerve, Peking University Third Hospital, Beijing, China.
Comput Methods Programs Biomed. 2023 Dec;242:107815. doi: 10.1016/j.cmpb.2023.107815. Epub 2023 Sep 15.
To explore the synergistic function of the ligaments in eye, the zonular fibres, that mediate change in eye lens shape to allow for focussing over different distances.
A set of 3D Finite Element models of the anterior eye together with a custom developed pre-stress modelling approach was proposed to simulate vision for distant objects (the unaccommodated state) to vision for near objects (accommodation). One of the five zonular groups was cut off in sequence creating five models with different zonular arrangements, the contribution of each zonular group was analysed by comparing results of each specific zonular-cut model with those from the all-zonules model in terms of lens shape and zonular tensions.
In the all-zonular model, the anterior and equatorial zonules carry the highest tensions. In the anterior zonular-cut model, the equatorial zonular tension increases while the posterior zonular tension decreases, resulting in an increase in the change in Central Optical Power (COP). In the equatorial zonular-cut model, both the anterior and posterior zonular tensions increase, causing a decreasing change in COP. The change in COP decreases only slightly in the other models. For vitreous zonular-cut models, little change was seen in either the zonular tension or the change in COP.
The anterior and the equatorial zonular fibres have the major influence on the change in lens optical power, with the anterior zonules having a negative effect and the equatorial zonules contributing a positive effect. The contribution to variations in optical power by the equatorial zonules is much larger than by the posterior zonules.
探讨眼部韧带——小带纤维的协同功能,该纤维介导晶状体形状变化,以实现对不同距离的聚焦。
提出了一组眼前部的三维有限元模型,并采用定制开发的预应力建模方法,以模拟从看远处物体(非调节状态)到看近处物体(调节状态)的视觉过程。依次切断五组小带中的一组,创建五个具有不同小带排列的模型,通过比较每个特定小带切断模型与全小带模型在晶状体形状和小带张力方面的结果,分析每组小带的贡献。
在全小带模型中,前部和赤道部小带承受的张力最高。在前部小带切断模型中,赤道部小带张力增加而后部小带张力降低,导致中央光焦度(COP)变化增加。在赤道部小带切断模型中,前部和后部小带张力均增加,导致COP变化减小。在其他模型中,COP变化仅略有下降。对于玻璃体小带切断模型,小带张力和COP变化均未见明显变化。
前部和赤道部小带纤维对晶状体光焦度变化有主要影响,前部小带起负面影响,赤道部小带起正面作用。赤道部小带对光焦度变化的贡献远大于后部小带。