Boosting nuclear-targeted photothermal-chemotherapy by NIR-responsive hybrid membrane camouflaged nanotherapeutics

IF 4.5 2区工程技术 Q2 NANOSCIENCE & NANOTECHNOLOGY Cancer Nanotechnology Pub Date : 2023-10-03 DOI:10.1186/s12645-023-00224-4

Xinyue Xing, Yuying Zeng, Wanqing Zhong, Wendai Cheng, Chengxin Zhou, Xiaoxu Lu, Liyun Zhong

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Abstract

Abstract Background Engineering nanotherapeutics have been extensively studied for cancer therapy. However, the therapeutic efficacy is still severely restricted by biophysiological barriers and intracellular accumulation. Although the biomimetic nanoparticles have improved the former issue, there is almost no breakthrough in researches of intracellular transport. Herein, we proposed a NIR-responsive nuclear-targeted hybrid membrane biomimetic Prussian blue drug-loading nanotherapeutics (PB@DN@M). Results The hybrid membrane coating bestows nanotherapeutics tumor targeting and immune escape ability, thus promoting the tumor enrichment of PB nanotherapeutics. The nuclear targeting function triggered by NIR enhances the cellular internalization and nuclear entry efficiency, resulting in a superadditive effect for boosting photothermal-chemotherapy efficacy. Moreover, taking advantage of non-interference Raman properties of PB, we can track the location and distribution of nanotherapeutics, which is beneficial for guiding precise synchronization of photothermal-chemotherapy. The results revealed that this PB@DN@M presented a remarkable therapeutic efficacy and significantly inhibited the tumor growth up to 87.17%. Conclusions Therefore, this spatiotemporal controllable biomimetic nanotherapeutics will provide a new insight and strategy for specific targeted therapy of tumors.

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nir反应性混合膜伪装纳米疗法促进核靶向光热化疗

摘要背景工程纳米疗法在癌症治疗中得到了广泛的研究。然而，其治疗效果仍然受到生物生理屏障和细胞内蓄积的严重限制。虽然仿生纳米颗粒改善了前者的问题，但在细胞内转运方面的研究几乎没有突破。在此，我们提出了一种nir响应核靶向杂交膜仿生普鲁士蓝载药纳米疗法(PB@DN@M)。结果杂化膜涂层赋予纳米治疗药物靶向性和免疫逃逸能力，从而促进PB纳米治疗药物的肿瘤富集。近红外触发的核靶向功能增强了细胞内化和核进入效率，产生超加性效应，提高光热化疗疗效。此外，利用PB的无干扰拉曼特性，我们可以跟踪纳米治疗药物的位置和分布，这有利于指导光热化疗的精确同步。结果显示，该PB@DN@M具有显著的治疗效果，对肿瘤生长的抑制作用高达87.17%。因此，这种时空可控的仿生纳米疗法将为肿瘤的特异性靶向治疗提供新的见解和策略。

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来源期刊

Cancer Nanotechnology Pharmacology, Toxicology and Pharmaceutics-Pharmaceutical Science

CiteScore

5.20

自引率

1.80%

发文量

审稿时长

15 weeks

期刊介绍： Aim: Recognizing cancer as a group of diseases caused by nanostructural problems (i.e. with DNA) and also that there are unique benefits to approaches inherently involving nanoscale structures and processes to treat the disease, the journal Cancer Nanotechnology aims to disseminate cutting edge research; to promote emerging trends in the use of nanostructures and the induction of nanoscale processes for the prevention, diagnosis, treatment of cancer; and to cover related ancillary areas. Scope: Articles describing original research in the use of nanostructures and the induction of nanoscale processes for the prevention, diagnosis and treatment of cancer (open submission process). Review, editorial and tutorial articles picking up on subthemes of emerging importance where nanostructures and the induction of nanoscale processes are used for the prevention, diagnosis and treatment of cancer.