Nanoparticle-based photodynamic therapy for targeted treatment of breast cancer

IF 5.45 Q1 Physics and Astronomy
Shivam Rajput , Rishabha Malviya , Sathvik Belagodu Sridhar
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引用次数: 0

Abstract

Breast cancer is the predominant malignancy afflicting women globally, profoundly influencing their physical and psychological well-being. In recent years, photodynamic therapy (PDT) has emerged as a viable non-invasive treatment modality. Photodynamic therapy utilizes photosensitizers activated by laser light in an oxygen-rich environment to selectively destroy cancer cells. This process produces reactive oxygen species (ROS) that efficiently eradicate tumor tissues. In the comparison of free photosensitizers and nanoparticles in PDT, nanoparticles offer significant benefits, such as increased solubility, enhanced biodistribution, and superior intercellular penetration, resulting in more effective targeting of cancer cells. Current research concentrates on the development of nanocarrier photosensitizers by non-covalent methods (including self-aggregation and interfacial polymerization) and covalent techniques (such as chemical immobilization). These nanoparticles may accumulate in tumors by passive and/or active targeting, guaranteeing both chemical and physical stability of the photosensitizer payload. Their advantageous traits namely remarkable stability, variable dimensions, and facile surface functionalization render nanoparticles especially suitable for biological applications. This article elucidates the processes of breast cancer treatment utilizing nanoparticles in photodynamic therapy, emphasizing recent progress in nanocarrier technologies and synergistic treatments. It seeks to deliver a thorough summary of existing knowledge, establishing a basis for novel research concepts and systematic assessments of potential results. The review also addresses the use of PDT with traditional medicines in breast cancer treatment, highlighting its potential to improve therapeutic efficacy.
基于纳米粒子的光动力疗法用于乳腺癌的靶向治疗
乳腺癌是困扰全球妇女的主要恶性肿瘤,对她们的身心健康造成了深远的影响。近年来,光动力疗法(PDT)已成为一种可行的非侵入性治疗方式。光动力疗法利用激光激活的光敏剂在富氧环境中选择性地破坏癌细胞。这一过程产生的活性氧(ROS)能有效地消灭肿瘤组织。在对比游离光敏剂和纳米粒子在光导疗法中的应用时,纳米粒子具有显著的优势,如溶解度更高、生物分布更广、细胞间渗透性更强,从而更有效地靶向癌细胞。目前的研究主要集中在通过非共价方法(包括自聚集和界面聚合)和共价技术(如化学固定)开发纳米载体光敏剂。这些纳米颗粒可通过被动和/或主动靶向作用在肿瘤内积聚,保证光敏剂有效载荷的化学和物理稳定性。纳米粒子具有显著的稳定性、尺寸可变性和表面功能化简便性等优点,因此特别适合生物应用。本文阐明了在光动力疗法中利用纳米粒子治疗乳腺癌的过程,强调了纳米载体技术和协同治疗的最新进展。文章力求全面总结现有知识,为新的研究概念和潜在结果的系统评估奠定基础。该综述还讨论了在乳腺癌治疗中将光动力疗法与传统药物结合使用的问题,强调了光动力疗法在提高疗效方面的潜力。
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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来源期刊
Nano-Structures & Nano-Objects
Nano-Structures & Nano-Objects Physics and Astronomy-Condensed Matter Physics
CiteScore
9.20
自引率
0.00%
发文量
60
审稿时长
22 days
期刊介绍: Nano-Structures & Nano-Objects is a new journal devoted to all aspects of the synthesis and the properties of this new flourishing domain. The journal is devoted to novel architectures at the nano-level with an emphasis on new synthesis and characterization methods. The journal is focused on the objects rather than on their applications. However, the research for new applications of original nano-structures & nano-objects in various fields such as nano-electronics, energy conversion, catalysis, drug delivery and nano-medicine is also welcome. The scope of Nano-Structures & Nano-Objects involves: -Metal and alloy nanoparticles with complex nanostructures such as shape control, core-shell and dumbells -Oxide nanoparticles and nanostructures, with complex oxide/metal, oxide/surface and oxide /organic interfaces -Inorganic semi-conducting nanoparticles (quantum dots) with an emphasis on new phases, structures, shapes and complexity -Nanostructures involving molecular inorganic species such as nanoparticles of coordination compounds, molecular magnets, spin transition nanoparticles etc. or organic nano-objects, in particular for molecular electronics -Nanostructured materials such as nano-MOFs and nano-zeolites -Hetero-junctions between molecules and nano-objects, between different nano-objects & nanostructures or between nano-objects & nanostructures and surfaces -Methods of characterization specific of the nano size or adapted for the nano size such as X-ray and neutron scattering, light scattering, NMR, Raman, Plasmonics, near field microscopies, various TEM and SEM techniques, magnetic studies, etc .
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