Folate-engineered chitosan nanoparticles: next-generation anticancer nanocarriers.

IF 27.7 1区医学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecular Cancer Pub Date : 2024-10-31 DOI:10.1186/s12943-024-02163-z

Prashant Kesharwani, Kratika Halwai, Saurav Kumar Jha, Mohammed H Al Mughram, Salem Salman Almujri, Waleed H Almalki, Amirhossein Sahebkar

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Abstract

Chitosan nanoparticles (NPs) are well-recognized as promising vehicles for delivering anticancer drugs due to their distinctive characteristics. They have the potential to enclose hydrophobic anticancer molecules, thereby enhancing their solubilities, permeabilities, and bioavailabilities; without the use of surfactant, i.e., through surfactant-free solubilization. This allows for higher drug concentrations at the tumor sites, prevents excessive toxicity imparted by surfactants, and could circumvent drug resistance. Moreover, biomedical engineers and formulation scientists can also fabricate chitosan NPs to slowly release anticancer agents. This keeps the drugs at the tumor site longer, makes therapy more effective, and lowers the frequency of dosing. Notably, some types of cancer cells (fallopian tube, epithelial tumors of the ovary, and primary peritoneum; lung, kidney, ependymal brain, uterus, breast, colon, and malignant pleural mesothelioma) have overexpression of folate receptors (FRs) on their outer surface, which lets folate-drug conjugate-incorporated NPs to target and kill them more effectively. Strikingly, there is evidence suggesting that the excessively produced FR&αgr (isoforms of the FR) stays consistent throughout treatment in ovarian and endometrial cancer, indicating resistance to conventional treatment; and in this regard, folate-anchored chitosan NPs can overcome it and improve the therapeutic outcomes. Interestingly, overly expressed FRs are present only in certain tumor types, which makes them a promising biomarker for predicting the effectiveness of FR-targeted therapy. On the other hand, the folate-modified chitosan NPs can also enhance the oral absorption of medicines, especially anticancer drugs, and pave the way for effective and long-term low-dose oral metronomic scheduling of poorly soluble and permeable drugs. In this review, we talked briefly about the techniques used to create, characterize, and tailor chitosan-based NPs; and delved deeper into the potential applications of folate-engineered chitosan NPs in treating various cancer types.

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叶酸工程壳聚糖纳米颗粒：新一代抗癌纳米载体。

壳聚糖纳米粒子（NPs）因其独特的特性而被公认为是一种很有前景的抗癌药物递送载体。它们有可能包裹疏水性抗癌分子，从而提高其溶解度、渗透性和生物利用度；无需使用表面活性剂，即通过无表面活性剂溶解。这样可以提高肿瘤部位的药物浓度，防止表面活性剂带来的过度毒性，并可避免耐药性。此外，生物医学工程师和制剂科学家还可以制造壳聚糖 NPs，以缓慢释放抗癌药物。这样，药物在肿瘤部位的停留时间就更长，治疗效果更好，用药频率也更低。值得注意的是，某些类型的癌细胞（输卵管、卵巢上皮瘤和原发性腹膜；肺、肾、脑上皮瘤、子宫、乳腺、结肠和恶性胸膜间皮瘤）外表面叶酸受体（FRs）过度表达，这使得叶酸-药物共轭的 NPs 能够更有效地靶向杀死它们。令人震惊的是，有证据表明，在卵巢癌和子宫内膜癌的整个治疗过程中，过量产生的 FR&αgr（FR 的异构体）始终保持不变，这表明它们对常规治疗产生了抗药性；在这方面，叶酸锚定壳聚糖 NPs 可以克服它，并改善治疗效果。有趣的是，过度表达的叶酸盐只存在于某些肿瘤类型中，这使其成为预测叶酸盐靶向治疗效果的一种有前景的生物标记物。另一方面，叶酸修饰的壳聚糖 NPs 还能促进药物尤其是抗癌药物的口服吸收，为溶解性和渗透性较差的药物的长期有效低剂量口服节律性给药铺平了道路。在这篇综述中，我们简要介绍了用于创建、表征和定制壳聚糖基 NPs 的技术，并深入探讨了叶酸工程壳聚糖 NPs 在治疗各种癌症类型中的潜在应用。

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.