Polydopamine-coated UiO-66 nanoparticles loaded with perfluorotributylamine/tirapazamine for hypoxia-activated osteosarcoma therapy

Chen, Hongfang; Fu, Yuli; Feng, Kai; Zhou, Yifan; Wang, Xin; Huang, Haohan; Chen, Yan; Wang, Wenhao; Xu, Yuanjing; Tian, Haijun; Mao, Yuanqing; Wang, Jinwu; Zhang, Zhiyuan

doi:10.1186/s12951-021-01013-0

Cited by 37 publications

(15 citation statements)

References 51 publications

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“…Using this method, non-porous nanomaterials can be combined with therapeutic molecules via electrostatic attraction, non-covalent hydrophobic interactions, π–π stacking, and hydrogen bonding. Benefiting from tunable pore, high specific surface areas, and active surfaces, some porous NPs can also be loaded using drugs via this method ( Chen et al, 2021 ). Therefore, postsynthetic encapsulation/loading is a suitable method for most MNPs; however, the difference is that for MNPs with pores, small drug molecules can be encapsulated inside the MNPs through the pore size; for MNPs without sufficient pore sizes or if the pores are already occupied, drug molecules can only be loaded onto the nanomaterial surface or functionalized modified surfaces.…”

Section: Loading Methods Of Mnpsmentioning

confidence: 99%

Metal-based nano-delivery platform for treating bone disease and regeneration

Liu

Xu²,

Qiao³

et al. 2022

Front. Chem.

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Owing to their excellent characteristics, such as large specific surface area, favorable biosafety, and versatile application, nanomaterials have attracted significant attention in biomedical applications. Among them, metal-based nanomaterials containing various metal elements exhibit significant bone tissue regeneration potential, unique antibacterial properties, and advanced drug delivery functions, thus becoming crucial development platforms for bone tissue engineering and drug therapy for orthopedic diseases. Herein, metal-based drug-loaded nanomaterial platforms are classified and introduced, and the achievable drug-loading methods are comprehensively generalized. Furthermore, their applications in bone tissue engineering, osteoarthritis, orthopedic implant infection, bone tumor, and joint lubrication are reviewed in detail. Finally, the merits and demerits of the current metal-based drug-loaded nanomaterial platforms are critically discussed, and the challenges faced to realize their future applications are summarized.

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Section: Loading Methods Of Mnpsmentioning

confidence: 99%

Metal-based nano-delivery platform for treating bone disease and regeneration

Liu

Xu²,

Qiao³

et al. 2022

Front. Chem.

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“…Starting from this, a number of sarcoma passively targeted DDS have been studied. An example is the study of Chen and colleagues who developed an mPEG-PLA-based nanosystem ( Chen et al, 2021 ) loaded with docetaxel assessing their passive targeting and activity in mice bearing S180 sarcoma tumor. Sasatsu et al (2008) synthesized a methoxypolyethylene glycol amine-poly (DL-lactic acid) copolymer nanoparticles loaded with pyrene-ended poly (DL-lactic acid) providing evidence of passive sarcoma-180 tumor targeting.…”

Section: Nanotechnology-based Platforms In Sarcoma Translational Rese...mentioning

confidence: 99%

The emerging role of cancer nanotechnology in the panorama of sarcoma

Mercatali

Vanni²,

Miserocchi³

et al. 2022

Front. Bioeng. Biotechnol.

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In the field of nanomedicine a multitude of nanovectors have been developed for cancer application. In this regard, a less exploited target is represented by connective tissue. Sarcoma lesions encompass a wide range of rare entities of mesenchymal origin affecting connective tissues. The extraordinary diversity and rarity of these mesenchymal tumors is reflected in their classification, grading and management which are still challenging. Although they include more than 70 histologic subtypes, the first line-treatment for advanced and metastatic sarcoma has remained unchanged in the last fifty years, excluding specific histotypes in which targeted therapy has emerged. The role of chemotherapy has not been completely elucidated and the outcomes are still very limited. At the beginning of the century, nano-sized particles clinically approved for other solid lesions were tested in these neoplasms but the results were anecdotal and the clinical benefit was not substantial. Recently, a new nanosystem formulation NBTXR3 for the treatment of sarcoma has landed in a phase 2-3 trial. The preliminary results are encouraging and could open new avenues for research in nanotechnology. This review provides an update on the recent advancements in the field of nanomedicine for sarcoma. In this regard, preclinical evidence especially focusing on the development of smart materials and drug delivery systems will be summarized. Moreover, the sarcoma patient management exploiting nanotechnology products will be summed up. Finally, an overlook on future perspectives will be provided.

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“…There are three general anticancer strategies based on tumor hypoxia: (i) harnessing it for the development of bioresponsive (hypoxia-responsive) nanomedicines; (ii) alleviating the hypoxia using vascular normalization agents (antiangiogenic therapy) or increasing oxygen level externally [oxygen delivery using hemoglobin ( 98 ) or perfluorocarbon] or internally [using oxygen generators called enzymes, which employ MnO 2 ( 99 ) and catalase (CAT) ( 100 ) to generate O 2 from H 2 O 2 present abundantly in TME]; and, finally, (iii) oxygen depletion or starvation therapy, which aims to kill tumor cells by exacerbation of hypoxia and oxygen/nutrient depletion, as practiced by vascular infarction/disruption therapy using vascular disrupting agents or delivery of thrombosis-inducing agents such as coagulase fusion proteins ( 101 , 102 ) or thrombin delivery ( 103 ) using a nanorobot to the tumor site to induce thrombosis selectively in tumor blood vessels. Oxygen depletion itself can be achieved externally by PDT and radiotherapy, which consumes intratumoral O 2 to generate ROS or endogenously by inherent oxygen-consuming materials such as magnesium silicide (Mg 2 Si) ( 104 ), perfluorotributylamine (PFTBA) ( 105 ), or glucose oxidase (GO X ) ( 106 ). Mostly, for a better efficacy, the combination of these approaches together ( 107 ) or with other approaches such as chemotherapy ( 99 ), radiotherapy, SDT ( 100 ), immunotherapy, and PDT ( 108 ) is desired.…”

Section: Tumor-penetrating Chitosan Nps Cross Biological and Microenv...mentioning

confidence: 99%

Tumor microenvironment penetrating chitosan nanoparticles for elimination of cancer relapse and minimal residual disease

et al. 2022

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Chitosan and its derivatives are among biomaterials with numerous medical applications, especially in cancer. Chitosan is amenable to forming innumerable shapes such as micelles, niosomes, hydrogels, nanoparticles, and scaffolds, among others. Chitosan derivatives can also bring unprecedented potential to cross numerous biological barriers. Combined with other biomaterials, hybrid and multitasking chitosan-based systems can be realized for many applications. These include controlled drug release, targeted drug delivery, post-surgery implants (immunovaccines), theranostics, biosensing of tumor-derived circulating materials, multimodal systems, and combination therapy platforms with the potential to eliminate bulk tumors as well as lingering tumor cells to treat minimal residual disease (MRD) and recurrent cancer. We first introduce different formats, derivatives, and properties of chitosan. Next, given the barriers to therapeutic efficacy in solid tumors, we review advanced formulations of chitosan modules as efficient drug delivery systems to overcome tumor heterogeneity, multi-drug resistance, MRD, and metastasis. Finally, we discuss chitosan NPs for clinical translation and treatment of recurrent cancer and their future perspective.

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Polydopamine-coated UiO-66 nanoparticles loaded with perfluorotributylamine/tirapazamine for hypoxia-activated osteosarcoma therapy

Cited by 37 publications

References 51 publications

Metal-based nano-delivery platform for treating bone disease and regeneration

Metal-based nano-delivery platform for treating bone disease and regeneration

The emerging role of cancer nanotechnology in the panorama of sarcoma

Tumor microenvironment penetrating chitosan nanoparticles for elimination of cancer relapse and minimal residual disease

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