G. F. Shtylev, I. Yu. Shishkin, S. A. Lapa, V. E. Shershov, V. E. Barsky, S. A. Polyakov, V. A. Vasiliskov, O. A. Zasedateleva, V. E. Kuznetsova, A. V. Chudinov
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引用次数: 0
Abstract
Objective: Polyethylene terephthalate (PET) is thermally stable, biocompatible, transparent in visible and near-infrared light. The study of grafting conditions and the distribution of reactive amino groups on the PET surface without affecting the polymer array makes it possible to change the surface properties in a directed manner. Methods: A method for obtaining active amino groups on the surface of polyethylene terephthalate (PET) substrate by reaction with ethylenediamine was developed. A method for quantitative estimation of the concentration and distribution of chemically accessible amino groups on the surface of PET substrate using cyanine dye Cy5 and digital fluorescence microscopy was developed. Results and Discussion: The PET surface during chemical modification remains without visible damage up to the concentration of amino groups 8 pmol/cm2, while surface degradation is observed at higher concentrations. Chemically available amino groups capable of covalently binding to Cy5 dye are distributed unevenly, which is probably due to the presence of amorphous and crystalline areas on the surface of PET substrates. Amino groups can be used for further chemical modification of the PET surface, grafting of various functional groups, and covalent binding to biomolecules, which opens up prospects for the wide use of inexpensive PET as functional substrates in biochips, biosensors, lab-on-a-chip devices, and other biotechnological applications.
目的:聚对苯二甲酸乙二醇酯(PET)具有热稳定性、生物相容性、在可见光和近红外线下透明。在不影响聚合物阵列的情况下,研究接枝条件和反应性氨基在 PET 表面的分布,可以有针对性地改变其表面特性。方法:开发了一种通过与乙二胺反应在聚对苯二甲酸乙二醇酯(PET)基材表面获得活性氨基的方法。开发了一种利用氰基染料 Cy5 和数字荧光显微镜定量估算 PET 底物表面化学可触及氨基的浓度和分布的方法。结果与讨论:在氨基浓度为 8 pmol/cm2 的情况下,PET 表面在化学修饰过程中不会出现明显的损伤,而在更高浓度的情况下,则会出现表面降解。能与 Cy5 染料共价结合的可用化学氨基基团分布不均,这可能是由于 PET 基质表面存在无定形区和结晶区。氨基基团可用于 PET 表面的进一步化学修饰、各种功能基团的接枝以及与生物大分子的共价结合,这为在生物芯片、生物传感器、片上实验室设备和其他生物技术应用中广泛使用廉价 PET 作为功能基底开辟了前景。
期刊介绍:
Russian Journal of Bioorganic Chemistry publishes reviews and original experimental and theoretical studies on the structure, function, structure–activity relationships, and synthesis of biopolymers, such as proteins, nucleic acids, polysaccharides, mixed biopolymers, and their complexes, and low-molecular-weight biologically active compounds (peptides, sugars, lipids, antibiotics, etc.). The journal also covers selected aspects of neuro- and immunochemistry, biotechnology, and ecology.