Stefanny Angela , Gianna Fadhilah , Wesley Wei-Wen Hsiao , Hsuan-Yi Lin , Joshua Ko , Steven Che-Wei Lu , Cheng-Chung Lee , Yu-Sheng Chang , Ching-Yu Lin , Huan-Cheng Chang , Wei-Hung Chiang
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引用次数: 0
Abstract
Rheumatoid arthritis (RA), a chronic inflammatory condition that affects persons between the ages of 20 and 40, causes synovium inflammation, cartilage loss, and joint discomfort as some of its symptoms. Diagnostic techniques for RA have traditionally been split into two main categories: imaging and serological tests. However, significant issues are associated with both of these methods. Imaging methods are costly and only helpful in people with obvious symptoms, while serological assays are time-consuming and require specialist knowledge. The drawbacks of these traditional techniques have led to the development of novel diagnostic approaches. The unique properties of nanomaterials make them well-suited as biosensors. Their compact dimensions are frequently cited for their outstanding performance, and their positive impact on the signal-to-noise ratio accounts for their capacity to detect biomarkers at low detection limits, with excellent repeatability and a robust dynamic range. In this review, we discuss the use of nanomaterials in RA theranostics. Scientists have recently synthesized, characterized, and modified nanomaterials and biomarkers commonly used to enhance RA diagnosis and therapy capabilities. We hope to provide scientists with the promising potential that nanomaterials hold for future theranostics and offer suggestions on further improving nanomaterials as biosensors, particularly for detecting autoimmune disorders.
类风湿性关节炎(RA)是一种慢性炎症,好发于20至40岁的人群,主要症状包括滑膜发炎、软骨脱落和关节不适。传统上,RA 的诊断技术主要分为两大类:影像学检查和血清学检查。然而,这两种方法都存在重大问题。影像学方法成本高昂,且只对症状明显的患者有帮助,而血清学检测则耗时长,且需要专业知识。这些传统技术的缺点促使人们开发新型诊断方法。纳米材料的独特性能使其非常适合用作生物传感器。纳米材料尺寸小巧,性能卓越,对信噪比的积极影响使其能够以较低的检测限检测生物标记物,并具有出色的重复性和强大的动态范围。在本综述中,我们将讨论纳米材料在 RA 治疗学中的应用。科学家们最近对常用的纳米材料和生物标记物进行了合成、表征和修饰,以提高 RA 诊断和治疗能力。我们希望向科学家们介绍纳米材料在未来治疗学中的巨大潜力,并就进一步改进纳米材料作为生物传感器(尤其是用于检测自身免疫性疾病)提出建议。
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SLAS Technology emphasizes scientific and technical advances that enable and improve life sciences research and development; drug-delivery; diagnostics; biomedical and molecular imaging; and personalized and precision medicine. This includes high-throughput and other laboratory automation technologies; micro/nanotechnologies; analytical, separation and quantitative techniques; synthetic chemistry and biology; informatics (data analysis, statistics, bio, genomic and chemoinformatics); and more.
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