Adsorption of rare bases on transition metal doped γ-graphyne nanosheets: a DFT study†

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-09-24 DOI:10.1039/D4CP03128H
Xia Zeng, Ruiying Zhang, Ruirui Li, Ruimei Li, Hong Cui, Caibin Zhao, Shengrui Zhang and Lingxia Jin
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Abstract

Detection of rare bases (RBs) is key to understanding biological complexity, rapidly diagnosing genetic diseases and advancing personalized medicine. Electrochemical sensors are one of the most promising methods for RB detection, but their low responsiveness limits their effectiveness. Therefore, enhancing selectivity and sensitivity is necessary. γ-Graphyne (γ-GY) has garnered significant attention due to its sp2 and sp hybrid carbon bonds and layered two-dimensional planar structure, as well as its extensive conjugated system, and sizable triangular hole. In this study, the structural characteristics, electronic properties, and sensing parameters of the adsorption involving RBs with both γ-GY and transition metal (Fe, Co, and Ni)-doped γ-graphyne (TM-GY) nanosheets are investigated using density functional theory calculations to evaluate the potential of nanosheets for sequencing RBs in DNA. The result shows that the adsorption interaction between RBs and γ-GY is weak physical adsorption, making it difficult to distinguish RBs. In contrast, the adsorption of RBs with TM-GY is stronger chemisorption and can be completely separated by translocation time and sensing response. Through translocation time calculations, we demonstrate the high selectivity of Ni-GY for RBs. Furthermore, sensitivity analysis reveals that Fe-GY exhibits excellent responsiveness to RBs. Our work reveals that the TM-GY nanosheets hold promise for detecting RBs compared with the γ-GY, and may provide valuable insights for the design of graphyne-based biosensors and catalysts.

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稀有碱在掺杂过渡金属的γ-石墨烯纳米片上的吸附:DFT 研究。
检测稀有碱基(RB)是了解生物复杂性、快速诊断遗传疾病和推进个性化医疗的关键。电化学传感器是最有前途的稀有碱基检测方法之一,但其低响应性限制了其有效性。因此,有必要提高选择性和灵敏度。γ-石墨炔(γ-GY)因其sp2和sp杂化碳键、层状二维平面结构、广泛的共轭体系和相当大的三角孔而备受关注。本研究利用密度泛函理论计算研究了γ-石墨炔和过渡金属(铁、钴和镍)掺杂的γ-石墨炔(TM-GY)纳米片吸附 RB 的结构特征、电子特性和传感参数,以评估纳米片用于 DNA 中 RB 测序的潜力。结果表明,RB 与 γ-GY 之间的吸附作用属于弱物理吸附,因此很难区分 RB。相比之下,RB 与 TM-GY 的吸附作用是较强的化学吸附作用,完全可以通过转位时间和传感反应来区分。通过易位时间计算,我们证明了 Ni-GY 对 RB 的高选择性。此外,灵敏度分析表明,Fe-GY 对 RB 具有极佳的响应性。我们的工作表明,与γ-GY相比,TM-GY纳米片在检测RB方面大有可为,并可能为设计基于石墨烯的生物传感器和催化剂提供有价值的见解。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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