酶介导的肿瘤内自组装纳米治疗剂用于增强成像和肿瘤治疗。

IF 6.9 2区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL
Yue Yuan, Jeff W M Bulte
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引用次数: 2

摘要

酶介导的肿瘤内自组装(EMISA)纳米治疗剂代表了一类新的智能药物,用于肿瘤的综合成像和治疗。癌细胞过度表达多种酶,这些酶对高代谢、快速增殖和组织侵袭转移至关重要。通过将含有酶特异性裂解位点的小分子偶联到适当的化学连接物上,有可能在具有靶酶的肿瘤细胞中诱导纳米结构的自组装。这种注射小治疗分子的方法最终在原位变成更大的纳米治疗剂,避免了注射更大的预组装纳米治疗剂时遇到的一些主要限制。EMISA纳米治疗的优势包括避免非特异性摄取和吞噬细胞的快速清除,增加细胞积聚,减少药物外排和延长细胞暴露时间,所有这些都导致放大的成像信号和治疗效果。本文综述了基于非共价相互作用和/或共价键的有机、无机或有机/无机杂化纳米治疗剂的制备方法。成像示例显示了荧光成像、核成像、光声成像、拉曼成像、计算机断层成像、生物发光成像和磁共振成像。本文分类如下:诊断工具>体内纳米诊断和成像生物学启发的纳米材料>肽基结构。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Enzyme-mediated intratumoral self-assembly of nanotheranostics for enhanced imaging and tumor therapy.

Enzyme-mediated intratumoral self-assembly of nanotheranostics for enhanced imaging and tumor therapy.

Enzyme-mediated intratumoral self-assembly of nanotheranostics for enhanced imaging and tumor therapy.

Enzyme-mediated intratumoral self-assembled (EMISA) nanotheranostics represent a new class of smart agents for combined imaging and therapy of cancer. Cancer cells overexpress various enzymes that are essential for high metabolism, fast proliferation, and tissue invasion and metastasis. By conjugating small molecules that contain an enzyme-specific cleavage site to appropriate chemical linkers, it is possible to induce self-assembly of nanostructures in tumor cells having the target enzyme. This approach of injecting small theranostic molecules that eventually become larger nanotheranostics in situ avoids some of the major limitations that are encountered when injecting larger, pre-assembled nanotheranostics. The advantage of EMISA nanotheranostics include the avoidance of nonspecific uptake and rapid clearance by phagocytic cells, increased cellular accumulation, reduced drug efflux and prolonged cellular exposure time, all of which lead to an amplified imaging signal and therapeutic efficacy. We review here the different approaches that can be used for preparing EMISA-based organic, inorganic, or organic/inorganic hybrid nanotheranostics based on noncovalent interactions and/or covalent bonding. Imaging examples are shown for fluorescence imaging, nuclear imaging, photoacoustic imaging, Raman imaging, computed tomography imaging, bioluminescent imaging, and magnetic resonance imaging. This article is categorized under: Diagnostic Tools > In Vivo Nanodiagnostics and Imaging Biology-Inspired Nanomaterials > Peptide-Based Structures.

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来源期刊
Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology
Wiley interdisciplinary reviews. Nanomedicine and nanobiotechnology NANOSCIENCE & NANOTECHNOLOGY-MEDICINE, RESEARCH & EXPERIMENTAL
CiteScore
16.60
自引率
2.30%
发文量
93
期刊介绍: Nanotechnology stands as one of the pivotal scientific domains of the twenty-first century, recognized universally for its transformative potential. Within the biomedical realm, nanotechnology finds crucial applications in nanobiotechnology and nanomedicine, highlighted as one of seven emerging research areas under the NIH Roadmap for Medical Research. The advancement of this field hinges upon collaborative efforts across diverse disciplines, including clinicians, biomedical engineers, materials scientists, applied physicists, and toxicologists. Recognizing the imperative for a high-caliber interdisciplinary review platform, WIREs Nanomedicine and Nanobiotechnology emerges to fulfill this critical need. Our topical coverage spans a wide spectrum, encompassing areas such as toxicology and regulatory issues, implantable materials and surgical technologies, diagnostic tools, nanotechnology approaches to biology, therapeutic approaches and drug discovery, and biology-inspired nanomaterials. Join us in exploring the frontiers of nanotechnology and its profound impact on biomedical research and healthcare.
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