用于MITF抗原和D5单克隆抗体的微反杠杆生物传感器的设计与仿真有限元分析和实验。

IF 1.9 4区生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Current protein & peptide science Pub Date : 2024-01-01 DOI:10.2174/0113892037259122231013153546

Pelin Akcali, Kübra Kelleci, Sevil Ozer

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引用次数: 0

摘要

背景：在过去的几十年里，生物传感器和微机电系统得到了快速的发展和极大的兴趣。诊断、医疗和化学应用的不断进步已在多个平台和工具中得到证明。在本研究中，将用于生物分子分析的微悬臂梁的分析和有限元分析结果与实验分析结果进行了比较。方法：本研究选用黑色素瘤生物标志物MITF抗原和抗MITF抗体（D5）作为生物分子。利用两种分子之间特定的相互作用动力学和分子间结合能力，通过对AFM悬臂梁进行功能化，设计了MEMS型微悬臂梁生物传感器。利用有限元法对悬臂梁微型生物传感器进行了表面功能化。由于MITF-D5之间的相互作用而产生的应力已由悬臂的谐振频率偏差确定。结果：仿真结果得到了分析计算和实验结果的支持。结论：与昂贵和耗时的实验方法相比，模拟研究的结果与实验和数学结果重叠，这一事实使我们能够获得更便宜、更快的答案。

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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Design and Simulation of the Microcantilever Biosensor for MITF Antigen and D5 Monoclonal Antibody Interaction Finite Element Analysis, and Experimental.

Background: Biosensors and MEMS have witnessed rapid development and enormous interest over the past decades. Constant advancement in diagnostic, medical, and chemical applications has been demonstrated in several platforms and tools. In this study, the analytical and FEA of the microcantilever used in biomolecular analyses were compared with the experimental analysis results.

Methods: In this study, MITF antigen, which is a melanoma biomarker, and anti-MITF antibody (D5) were selected as biomolecules. A MEMS-type microcantilever biosensor was designed by functionalizing the AFM cantilever by utilizing the specific interaction dynamics and intermolecular binding ability between both molecules. Surface functionalization of cantilever micro biosensors was performed by using FEA. The stress that will occur as a result of the interactions between the MITF-D5 has been determined from the deviation in the resonant frequency of the cantilever.

Results: It has been found that the simulation results are supported by analytical calculations and experimental results.

Conclusion: The fact that the results of the simulation study overlap with the experimental and mathematical results allows us to get much cheaper and faster answers compared to expensive and time-consuming experimental approaches.

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来源期刊

Current protein & peptide science 生物-生化与分子生物学

CiteScore

5.20

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： Current Protein & Peptide Science publishes full-length/mini review articles on specific aspects involving proteins, peptides, and interactions between the enzymes, the binding interactions of hormones and their receptors; the properties of transcription factors and other molecules that regulate gene expression; the reactions leading to the immune response; the process of signal transduction; the structure and function of proteins involved in the cytoskeleton and molecular motors; the properties of membrane channels and transporters; and the generation and storage of metabolic energy. In addition, reviews of experimental studies of protein folding and design are given special emphasis. Manuscripts submitted to Current Protein and Peptide Science should cover a field by discussing research from the leading laboratories in a field and should pose questions for future studies. Original papers, research articles and letter articles/short communications are not considered for publication in Current Protein & Peptide Science.