Exosomes in cancer nanomedicine: biotechnological advancements and innovations

IF 27.7 1区医学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecular Cancer Pub Date : 2025-06-07 DOI:10.1186/s12943-025-02372-0

Jacky J. J. Liu, Duanrui Liu, Sally K. Y. To, Alice S. T. Wong

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引用次数: 0

Abstract

Exosomes, as natural intercellular messengers, are gaining prominence as delivery vehicles in nanomedicine, offering a superior alternative to conventional synthetic nanoparticles for cancer therapeutics. Unlike lipid, polymer, or metallic nanoparticles, which often face challenges related to immunogenicity, targeting precision, and off-tumor toxicity, exosomes can effectively encapsulate a diverse range of therapeutic agents while exhibiting low toxicity, favorable pharmacokinetics, and organotropic properties. This review examines recent advancements in exosome bioengineering over the past decade. Innovations such as microfluidics-based platforms, nanoporation, fusogenic hybrids, and genetic engineering have significantly improved loading efficiencies, production scalability, and pharmacokinetics of exosomes. These advancements facilitate tumor-specific cargo delivery, resulting in substantial improvements in retention and efficacy essential for clinical success. Moreover, enhanced biodistribution, targeting, and bioavailability—through strategies such as cell selection, surface modifications, membrane composition alterations, and biomaterial integration—suggests a promising future for exosomes as an ideal nanomedicine delivery platform. We also highlight the translational impact of these strategies through emerging clinical trials. Additionally, we outline a framework for clinical translation that focuses on: cargo selection, organotropic cell sourcing, precision loading methodologies, and route-specific delivery optimization. In summary, this review emphasizes the potential of exosomes to overcome the pharmacokinetic and safety challenges that have long impeded oncology drug development, thus enabling safer and more effective cancer treatments.

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肿瘤纳米医学中的外泌体：生物技术的进步和创新

外泌体作为天然的细胞间信使，在纳米医学中作为递送载体日益突出，为癌症治疗提供了传统合成纳米粒子的优越替代方案。脂质、聚合物或金属纳米颗粒经常面临与免疫原性、靶向精度和非肿瘤毒性相关的挑战，而外泌体可以有效地包裹各种治疗药物，同时表现出低毒性、良好的药代动力学和有机物性。本文综述了近十年来外泌体生物工程的最新进展。基于微流体的平台、纳米穿孔、融合杂交和基因工程等创新技术显著提高了外泌体的装载效率、生产可扩展性和药代动力学。这些进步促进了肿瘤特异性的货物递送，从而大大提高了保留和疗效，这对临床成功至关重要。此外，通过细胞选择、表面修饰、膜组成改变和生物材料整合等策略，增强生物分布、靶向性和生物利用度，表明外泌体作为理想的纳米药物递送平台具有广阔的前景。我们还通过新兴的临床试验强调了这些策略的转化影响。此外，我们概述了临床翻译的框架，重点是：货物选择，嗜器官细胞来源，精确装载方法和路线特定的交付优化。总之，这篇综述强调了外泌体克服长期阻碍肿瘤药物开发的药代动力学和安全性挑战的潜力，从而实现更安全、更有效的癌症治疗。

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

Molecular Cancer 医学-生化与分子生物学

CiteScore

54.90

自引率

2.70%

发文量

224

审稿时长

2 months

期刊介绍： Molecular Cancer is a platform that encourages the exchange of ideas and discoveries in the field of cancer research, particularly focusing on the molecular aspects. Our goal is to facilitate discussions and provide insights into various areas of cancer and related biomedical science. We welcome articles from basic, translational, and clinical research that contribute to the advancement of understanding, prevention, diagnosis, and treatment of cancer. The scope of topics covered in Molecular Cancer is diverse and inclusive. These include, but are not limited to, cell and tumor biology, angiogenesis, utilizing animal models, understanding metastasis, exploring cancer antigens and the immune response, investigating cellular signaling and molecular biology, examining epidemiology, genetic and molecular profiling of cancer, identifying molecular targets, studying cancer stem cells, exploring DNA damage and repair mechanisms, analyzing cell cycle regulation, investigating apoptosis, exploring molecular virology, and evaluating vaccine and antibody-based cancer therapies. Molecular Cancer serves as an important platform for sharing exciting discoveries in cancer-related research. It offers an unparalleled opportunity to communicate information to both specialists and the general public. The online presence of Molecular Cancer enables immediate publication of accepted articles and facilitates the presentation of large datasets and supplementary information. This ensures that new research is efficiently and rapidly disseminated to the scientific community.