Deformable nanocarriers for enhanced drug delivery and cancer therapy

Ziyang Cao, Jing Liu, Xianzhu Yang
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Abstract

Recently, the field of nanomedicine has witnessed substantial advancements in the development of nanocarriers for targeted drug delivery, emerges as promising platforms to enhance therapeutic efficacy and minimize adverse effects associated with conventional chemotherapy. Notably, deformable nanocarriers have garnered considerable attention due to their unique capabilities of size changeable, tumor-specific aggregation, stimuli-triggered disintegration, and morphological transformations. These deformable nanocarriers present significant opportunities for revolutionizing drug delivery strategies, by responding to specific stimuli or environmental cues, enabling achieved various functions at the tumor site, including size-shrinkage nanocarriers enhance drug penetration, aggregative nanocarriers enhance retention effect, disintegrating nanocarriers enable controlled drug release, and shape-changing nanocarriers improve cellular uptake, allowing for personalized treatment approaches and combination therapies. This review provides an overview of recent developments and applications of deformable nanocarriers for enhancing tumor therapy, underscores the diverse design strategies employed to create deformable nanocarriers and elucidates their remarkable potential in targeted tumor therapy.

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用于增强药物输送和癌症治疗的可变形纳米载体
近来,纳米医学领域在开发用于靶向给药的纳米载体方面取得了长足的进步,纳米载体已成为提高疗效和减少传统化疗相关不良反应的前景广阔的平台。值得注意的是,可变形纳米载体因其具有尺寸可变、肿瘤特异性聚集、刺激触发分解和形态转化等独特功能而备受关注。这些可变形纳米载体可对特定刺激或环境线索做出反应,从而在肿瘤部位实现各种功能,包括尺寸收缩纳米载体可增强药物渗透性,聚集纳米载体可增强药物保留效果,崩解纳米载体可实现药物的可控释放,形态变化纳米载体可提高细胞摄取率,从而实现个性化治疗方法和联合疗法。本综述概述了可变形纳米载体在加强肿瘤治疗方面的最新发展和应用,强调了创造可变形纳米载体所采用的各种设计策略,并阐明了它们在肿瘤靶向治疗方面的巨大潜力。
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Issue Information Back Cover: High-yield upcycling of feather wastes into solid-state ultra-long phosphorescence carbon dots for advanced anticounterfeiting and information encryption (EXP2 6/2024) Frontispiece: Advancements and challenges in brain cancer therapeutics (EXP2 6/2024) Front Cover: Piezoelectric stimulation enhances bone regeneration in alveolar bone defects through metabolic reprogramming of macrophages (EXP2 6/2024) Pioneering Exploration for a lasting and sustainable future
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