The Structure and Mechanical Properties of Type IV Collagen in Lens Basement Membrane: Deterioration with Age and Glycation Reviewed

IF 1.7 Q2 REHABILITATION

Scandinavian Journal of Disability Research Pub Date : 2022-11-29 DOI:10.57197/jdr-2022-0003

D. A. Bradley

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引用次数: 0

Abstract

Biomedical physics seeks to confront the amazingly intricate sets of interlinked processes that when in synchrony sustain life. In so doing, questions arise regarding the functionality of cells, organised tissues and organs and the myriad interactional processes required, and also as to how the onset of disease limits viability and what possible repair processes can be caused to happen, including in biosynthetic routes. It is clearly a multidisciplinary field providing a multi-pronged array of endeavours, bringing into play concepts and tools within the armoury of physics, chemistry, engineering, mathematics, and all of the applied areas that arise from these. As expected, the pursuit is beset by ignorance and in the absence of a polymath, the ability to progress is clearly a team effort. Not least among the challenges are that oftentimes the medium under investigation no longer enjoys the vitality of life, including when using in vitro techniques acknowledging that in excised tissues repair processes are clearly inoperative. As such, questions inevitably arise as to whether the results of an investigation bear resemblance to that of the living entity. Here, we will focus on just one example of such a pursuit, namely investigations of degraded vision arising from alterations in the basement membrane (BM). We address alterations that may arise from diabetes and ageing, which are changes that bring about life-altering disability. In examining this one area of biophysical investigation, we hope that the reader will gain a degree of appreciation of the need for such studies even if, as here, we simply represent just one particular aspect of what are clearly complex areas. At the outset, we simply mention that the BM forming the eye lens capsule is a highly specialised form of extracellular matrix in which the major structural element is a network of type IV collagen. Changes in the structure and mechanical properties of the BM are believed to be associated with the pathophysiology of ageing and diseases, including diabetes and cancer.

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晶状体基底膜中IV型胶原的结构和力学性能:随着年龄和糖基化的恶化

生物医学物理学试图面对惊人的错综复杂的相互关联的过程，当它们同步维持生命时。在这样做的过程中，出现了关于细胞、有组织组织和器官的功能以及所需的无数相互作用过程的问题，也出现了关于疾病的发作如何限制生存能力以及可能导致哪些修复过程发生的问题，包括在生物合成途径中。它显然是一个多学科领域，提供了多管齐下的一系列努力，在物理、化学、工程、数学以及由此产生的所有应用领域的军械库中引入概念和工具。不出所料，这种追求被无知所困扰，在没有博学多才的情况下，进步的能力显然需要团队的努力。其中最重要的挑战是，经常被研究的培养基不再具有生命的活力，包括在使用体外技术时，承认在切除的组织中修复过程显然不起作用。因此，不可避免地会出现这样的问题，即调查的结果是否与生物实体的结果相似。在这里，我们将只关注这样一个追求的例子，即研究由基底膜(BM)改变引起的视力下降。我们处理可能由糖尿病和衰老引起的变化，这些变化会导致改变生活的残疾。在研究生物物理研究的这一领域时，我们希望读者能对这类研究的必要性有一定程度的理解，即使像这里一样，我们只是简单地代表了这一明显复杂领域的一个特定方面。首先，我们简单地提到，形成眼球晶状体囊的基底膜是一种高度特化的细胞外基质，其主要结构元素是IV型胶原网络。脑基结构和机械特性的变化被认为与衰老和疾病(包括糖尿病和癌症)的病理生理学有关。

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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