将 TGF-β 抑制剂包裹在巨噬细胞启发的多功能纳米颗粒中,用于癌症联合免疫疗法。

IF 8.1 Q1 ENGINEERING, BIOMEDICAL
Jaehyun Kim, Minjeong Kim, Seok-Beom Yong, Heesoo Han, Seyoung Kang, Shayan Fakhraei Lahiji, Sangjin Kim, Juhyeong Hong, Yuha Seo, Yong-Hee Kim
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引用次数: 0

摘要

背景:癌症免疫疗法,尤其是免疫检查点抑制剂的出现,给抗癌治疗带来了革命性的变化。然而,据报道,这些疗法只对有限范围的癌症有效,而且会引起与免疫相关的不良反应。因此,为了使实体瘤免疫疗法具有更广泛的适用性和更高的反应性,对肿瘤微环境进行免疫调节至关重要。转化生长因子-β(TGF-β)通过促进巨噬细胞的 M2 型分化和促进癌细胞转移,被认为会降低免疫治疗的反应性:在这项研究中,我们开发了负载 TGF-βR1 激酶抑制剂 SD-208 (M[式:见正文]-SDNP)的巨噬细胞膜包被纳米颗粒。通过体外和体内实验,全面评估了对 M2 巨噬细胞极化和癌细胞上皮细胞向间质转化(EMT)的抑制作用。在正位乳腺癌模型和静脉注射转移模型中研究了 M[式:见正文]-SDNP 的生物分布研究和体内治疗效果:结果:M[式:见正文]-SDNPs通过特异性肿瘤靶向和阻断M2型巨噬细胞分化,有效抑制肿瘤转移,并将免疫抑制性肿瘤微环境(冷瘤)转化为免疫刺激性肿瘤微环境(热瘤)。M[式中:见正文]-SDNPs可显著增加肿瘤组织中细胞毒性T淋巴细胞(CTL)的数量,从而显著提高对免疫检查点抑制剂的反应性,这与抗PD-1抗体一起显示出强大的抗癌效果:总之,M[式:见正文]-SDNPs 和抗-PD-1 抗体的联合治疗大大提高了对免疫检查点抑制剂的反应性,并显示出强大的抗癌效果。这为未来利用生物启发纳米技术提高癌症免疫疗法疗效的治疗策略指明了方向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Engineering TGF-β inhibitor-encapsulated macrophage-inspired multi-functional nanoparticles for combination cancer immunotherapy.

Background: The emergence of cancer immunotherapies, notably immune checkpoint inhibitors, has revolutionized anti-cancer treatments. These treatments, however, have been reported to be effective in a limited range of cancers and cause immune-related adverse effects. Thus, for a broader applicability and enhanced responsiveness to solid tumor immunotherapy, immunomodulation of the tumor microenvironment is crucial. Transforming growth factor-β (TGF-β) has been implicated in reducing immunotherapy responsiveness by promoting M2-type differentiation of macrophages and facilitating cancer cell metastasis.

Methods: In this study, we developed macrophage membrane-coated nanoparticles loaded with a TGF-βR1 kinase inhibitor, SD-208 (M[Formula: see text]-SDNP). Inhibitions of M2 macrophage polarization and epithelial-to-mesenchymal transition (EMT) of cancer cells were comprehensively evaluated through in vitro and in vivo experiments. Bio-distribution study and in vivo therapeutic effects of M[Formula: see text]-SDNP were investigated in orthotopic breast cancer model and intraveneously injected metastasis model.

Results: M[Formula: see text]-SDNPs effectively inhibited cancer metastasis and converted the immunosuppressive tumor microenvironment (cold tumor) into an immunostimulatory tumor microenvironment (hot tumor), through specific tumor targeting and blockade of M2-type macrophage differentiation. Administration of M[Formula: see text]-SDNPs considerably augmented the population of cytotoxic T lymphocytes (CTLs) in the tumor tissue, thereby significantly enhancing responsiveness to immune checkpoint inhibitors, which demonstrates a robust anti-cancer effect in conjunction with anti-PD-1 antibodies.

Conclusion: Collectively, responsiveness to immune checkpoint inhibitors was considerably enhanced and a robust anti-cancer effect was demonstrated with the combination treatment of M[Formula: see text]-SDNPs and anti-PD-1 antibody. This suggests a promising direction for future therapeutic strategies, utilizing bio-inspired nanotechnology to improve the efficacy of cancer immunotherapy.

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