Photodynamic therapy of cancer using graphene nanomaterials.

Expert opinion on drug delivery Pub Date : 2024-09-01 Epub Date: 2024-09-02 DOI:10.1080/17425247.2024.2398604
Sanjay Tiwari, Binny A Rudani, Priyanka Tiwari, Pratap Bahadur, Swaran J S Flora
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Abstract

Introduction: High incidence and fatality rates of cancer remain a global challenge. The success of conventional treatment modalities is being questioned on account of adverse effects. Photodynamic therapy (PDT) is a potential alternative. It utilizes a combination of photosensitizer (PS), light and oxygen to target the tissues locally, thereby minimizing the damage to neighboring healthy tissues. Conventional PSs suffer from poor selectivity, high hydrophobicity and sub-optimal yield of active radicals. Graphene nanomaterials (GNs) exhibit interesting particulate and photophysical properties in the context of their use in PDT.

Area covered: We focus on describing the mechanistic aspects of PDT-mediated elimination of cancer cells and the subsequent development of adaptive immunity. After covering up-to-date literature on the significant enhancement of PDT capability with GNs, we have discussed the probability of combining PDT with chemo-, immuno-, and photothermal therapy to make the treatment more effective.

Expert opinion: GNs can be synthesized in various size ranges, and their biocompatibility can be improved through surface functionalization and doping. These can be used as PS to generate ROS or conjugated with other PS molecules for treating deep-seated tumors. With increasing evidence on biosafety, such materials offer hope as antitumor therapeutics.

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利用石墨烯纳米材料对癌症进行光动力治疗。
导言:癌症的高发病率和高死亡率仍然是一项全球性挑战。传统治疗方法因其不良反应而备受质疑。光动力疗法(PDT)是一种潜在的替代疗法。它利用光敏剂(PS)、光和氧的组合,以局部组织为目标,从而最大限度地减少对邻近健康组织的损害。传统的光敏剂存在选择性差、疏水性高和活性自由基产量不理想等问题。石墨烯纳米材料(GNs)在用于光透射疗法方面表现出有趣的颗粒和光物理特性:我们的重点是描述 PDT 介导的消灭癌细胞的机理方面以及适应性免疫的后续发展。在介绍了有关利用 GNs 显著增强光动力疗法能力的最新文献之后,我们还讨论了将光动力疗法与化疗、免疫疗法和光热疗法相结合,使治疗更加有效的可能性:GNs 可以合成为各种尺寸范围的材料,其生物相容性可以通过表面功能化和掺杂得到改善。它们可用作产生 ROS 的 PS,或与其他 PS 分子共轭用于治疗深部肿瘤。随着生物安全性证据的增加,这类材料有望成为抗肿瘤治疗剂。
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