通过分析线性和环状聚合物接枝基底揭示水合水对聚合物界面生物反应性的影响。

IF 2.9 3区 化学 Q3 CHEMISTRY, PHYSICAL Soft Matter Pub Date : 2024-11-20 DOI:10.1039/d4sm00977k
Shin-Nosuke Nishimura, Naoya Kurahashi, Shohei Shiomoto, Yoshihisa Harada, Masaru Tanaka
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引用次数: 0

摘要

由于聚合物基质的水合水可能不同于最外层聚合物表面的水合水,因此使用大多数传统表征方法无法充分研究生物材料-生物流体界面的过程及其水合水的作用。为了弥补这一缺陷,本文用线性聚(2-甲氧基乙基丙烯酸酯)和环状聚(2-甲氧基乙基丙烯酸酯)改性金基底,分别制备出 gl-PMEA 和 gc-PMEA 表面,作为与血液接触的医疗设备最外层表面的模型。这两种表面都能抑制人体血小板的粘附,但对正常细胞和肿瘤细胞的粘附行为却不尽相同,尽管它们具有相同的固定端单位面积密度。在潮湿条件下,使用石英晶体微天平 (QCM)、频率调制原子力显微镜 (FM-AFM) 和 X 射线发射光谱 (XES) 测量方法对这两种表面进行了分析,以明确生物反应性与水合水之间的关系。QCM 测量结果表明,两种接枝-PMEA 都是水合的。FM-AFM 观察结果表明,gc-PMEA 的溶胀层更厚。为了合理解释表面水合状态的差异,我们在能够控制水合水分子数量的条件下进行了 XES 测量。在低含水量区域,水分子之间的氢键或相互作用在 gl-PMEA 附近形成,而 gc-PMEA 则没有。因此,促进中间水形成的 gc-PMEA 表面的初始水合行为与 gl-PMEA 表面不同。结果表明,调整和优化最外层生物材料表面的水合状态可以控制生物反应性,包括选择性地分离肿瘤细胞。
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Effects of hydration water on bioresponsiveness of polymer interfaces revealed by analysis of linear and cyclic polymer-grafted substrates.

Given that the hydration water of polymer matrices may differ from that of outermost polymer surfaces, processes at biomaterial-biofluid interfaces and role of hydration water therein cannot be adequately examined using most conventional characterization methods. To bridge this gap, a gold substrate was herein modified with linear and cyclic poly(2-methoxyethyl acrylate) to prepare gl-PMEA and gc-PMEA surfaces, respectively, as models for the outermost surfaces of blood-contacting medical devices. Both surfaces suppressed the adhesion of human platelets but differed in the adhesion behaviors of normal and tumor cells despite having the same areal density of fixed-end units. The surfaces were analyzed using quartz crystal microbalance (QCM), frequency modulation atomic force microscopy (FM-AFM), and X-ray emission spectroscopy (XES) measurements under wet conditions to clarify the relationship between bioresponsivity and hydration water. QCM measurements provided evidence that both grafted-PMEA were hydrated. FM-AFM observations revealed that the swelling layer was thicker for gc-PMEA. To rationalize the differences in the surface hydration states, we performed XES measurements under conditions enabling control over the number of hydration water molecules. In the low-water-content region, hydrogen bonds or interactions between water molecules developed in the vicinity of gl-PMEA but not gc-PMEA. Thus, the initial hydration behavior of the gc-PMEA surface, which promoted intermediate water formation, was different from that of the gl-PMEA surface. The results suggested that the adjustment and optimization of the hydration state of outermost biomaterial surfaces enable the control of bioresponsivity, including the selective isolation of tumor cells.

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来源期刊
Soft Matter
Soft Matter 工程技术-材料科学:综合
CiteScore
6.00
自引率
5.90%
发文量
891
审稿时长
1.9 months
期刊介绍: Where physics meets chemistry meets biology for fundamental soft matter research.
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