Ultrasmall BiOI Quantum Dots with Efficient Renal Clearance for Enhanced Radiotherapy of Cancer

Wang, Xin; Guo, Zhao; Zhang, Chenyang; Zhu, Shuang; Li, Lele; Gu, Zhennan; Zhao, Yuliang

doi:10.1002/advs.201902561

Cited by 66 publications

(50 citation statements)

References 50 publications

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“…And they have developed many novel semiconductor‐catalytic nanomaterials to apply in triggering H 2 O 2 for ROS production under X‐ray irradiation, such as BiOI QDs, Au‐Bi 2 S 3 NPs and bismuth heteropolytungstate [BiP 5 W 30 O 110 ] 12‐ (BiP 5 W 30 ) nanoclusters. [ 203–205 ]…”

Section: Ros‐associated Nanomedicines For Disease Treatmentsmentioning

confidence: 99%

“…[ 226 ] Besides that, in recent years, many studies indicated that semiconductor nanomaterial with high‐Z elements can directly be activated by X‐ray for ROS generation via a radiocatalytic process, such as BiOI QDs, Bi 2 WO 6 , WO 3 ‐Ag 2 WO 4 NPs, Au‐Bi 2 S 3 NPs and bismuth heteropolytungstate [BiP 5 W 30 O 110 ] 12‐ (BiP 5 W 30 ) nanoclusters, etc. [ 203–205,254 ] In the radiocatalytic process, these semiconductor nanomaterial can generate a lot of e − –h + pairs under X‐ray irradiation. These highly active e − –h + pairs can react with adjacent molecules such as O 2 and H 2 O to enhance ROS generation.…”

Section: Principles For the Design Of Ros‐associated Nanomedicinesmentioning

confidence: 99%

“…[ 292 ] Here, vascular disruption can improve the blood vessel permeability by employing physical forces such as heat, US and radiation, as well as introducing vascular disrupting agents. [ 203,293–295 ] Vascular normalization for restoring blood supply is usually realized by using anti‐angiogenic agents to inhibit rapid formation of dysfunctional vascular networks, ultimately inducing homogeneous distribution of therapeutic agents inside tumor. [ 292 ] While for the modulation of ECM, it is mainly achieved through blocking the ECM synthesis or depleting ECM with the aid of nanosystems.…”

Section: Principles For the Design Of Ros‐associated Nanomedicinesmentioning

confidence: 99%

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Reactive Oxygen Species‐Regulating Strategies Based on Nanomaterials for Disease Treatment

et al. 2020

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Reactive oxygen species (ROS) play an essential role in physiological and pathological processes. Studies on the regulation of ROS for disease treatments have caused wide concern, mainly involving the topics in ROS‐regulating therapy such as antioxidant therapy triggered by ROS scavengers and ROS‐induced toxic therapy mediated by ROS‐elevation agents. Benefiting from the remarkable advances of nanotechnology, a large number of nanomaterials with the ROS‐regulating ability are developed to seek new and effective ROS‐related nanotherapeutic modalities or nanomedicines. Although considerable achievements have been made in ROS‐based nanomedicines for disease treatments, some fundamental but key questions such as the rational design principle for ROS‐related nanomaterials are held in low regard. Here, the design principle can serve as the initial framework for scientists and technicians to design and optimize the ROS‐regulating nanomedicines, thereby minimizing the gap of nanomedicines for biomedical application during the design stage. Herein, an overview of the current progress of ROS‐associated nanomedicines in disease treatments is summarized. And then, by particularly addressing these known strategies in ROS‐associated therapy, several fundamental and key principles for the design of ROS‐associated nanomedicines are presented. Finally, future perspectives are also discussed in depth for the development of ROS‐associated nanomedicines.

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Section: Ros‐associated Nanomedicines For Disease Treatmentsmentioning

confidence: 99%

Section: Principles For the Design Of Ros‐associated Nanomedicinesmentioning

confidence: 99%

Section: Principles For the Design Of Ros‐associated Nanomedicinesmentioning

confidence: 99%

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Reactive Oxygen Species‐Regulating Strategies Based on Nanomaterials for Disease Treatment

et al. 2020

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“…However, normal tissues surrounding the tumors often suffer serious damage under high dose ionizing radiation because of nonspecific interactions. Thus, radiosensitizers have been employed to enhance the effect of RT under low-dose ionizing radiation by increasing the radiosensitivity of tumor cells 84 . Similar to CT contrast agents, nanomaterials composed of high atomic number metals have been developed as potential radiosensitizers to enhance the efficiency of RT.…”

Section: Cancer Therapy Using Pd-based Nanomaterialsmentioning

confidence: 99%

Palladium-based nanomaterials for cancer imaging and therapy

Liu

Chen

et al. 2020

Theranostics

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In recent decade, palladium-based (Pd-based) nanomaterials have shown significant potential for biomedical applications because of their unique optical properties, excellent biocompatibility and high stability in physiological environment. Compared with other intensively studied noble nanomaterials, such as gold (Au) and silver (Ag) nanomaterials, research on Pd-based nanomaterials started late, but the distinctive features, such as high photothermal conversion efficiency and high photothermal stability, have made them getting great attention in the field of nanomedicine. The goal of this review is to provide a comprehensive and critical perspective on the recent progress of Pd-based nanomaterials as imaging contrast agents and therapeutic agents. The imaging section focuses on applications in photoacoustic (PA) imaging, single-photon emission computed tomography (SPECT) imaging, computed tomography (CT) imaging and magnetic resonance (MR) imaging. For treatment of cancer, single photothermal therapy (PTT) and PTT combined with other therapeutic modalities will be discussed. Finally, the safety concerns, forthcoming challenges and perspective of Pd-based nanomaterials on biomedical applications will be presented.

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“…Cu‐based chemical‐driven ROS‐ECBs, such as Cu 2+ ‐doped biomaterials (Li et al, 2019; Liu et al, 2019a; Wang et al, 2019), copper sulfide (Pan et al, 2020; Wang et al, 2020), and Cu 2‐ x Se (Wang, Guo, et al, 2020), exhibited excellent performance in CDT compared with Fe‐based chemical‐driven ROS‐ECBs. It has been reported that the Cu + ‐catalyzed Fenton‐like reaction with the high reaction rate could occur in a wider range of pH compared with Fe 2+ (Wang et al, 2020).…”

Section: Energy‐converting Biomaterials For Cancer Therapymentioning

confidence: 99%

Energy‐converting biomaterials for cancer therapy: Category, efficiency, and biosafety

Dong

Sun

et al. 2020

WIREs Nanomed Nanobiotechnol

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Energy‐converting biomaterials (ECBs)‐mediated cancer‐therapeutic modalities have been extensively explored, which have achieved remarkable benefits to overwhelm the obstacles of traditional cancer‐treatment modalities. Energy‐driven cancer‐therapeutic modalities feature their distinctive merits, including noninvasiveness, low mammalian toxicity, adequate therapeutic outcome, and optimistical synergistic therapeutics. In this advanced review, the prevailing mainstream ECBs can be divided into two sections: Reactive oxygen species (ROS)‐associated energy‐converting biomaterials (ROS‐ECBs) and hyperthermia‐related energy‐converting biomaterials (H‐ECBs). On the one hand, ROS‐ECBs can transfer exogenous or endogenous energy (such as light, radiation, ultrasound, or chemical) to generate and release highly toxic ROS for inducing tumor cell apoptosis/necrosis, including photo‐driven ROS‐ECBs for photodynamic therapy, radiation‐driven ROS‐ECBs for radiotherapy, ultrasound‐driven ROS‐ECBs for sonodynamic therapy, and chemical‐driven ROS‐ECBs for chemodynamic therapy. On the other hand, H‐ECBs could translate the external energy (such as light and magnetic) into heat for killing tumor cells, including photo‐converted H‐ECBs for photothermal therapy and magnetic‐converted H‐ECBs for magnetic hyperthermia therapy. Additionally, the biosafety issues of ECBs are expounded preliminarily, guaranteeing the ever‐stringent requirements of clinical translation. Finally, we discussed the prospects and facing challenges for constructing the new‐generation ECBs for establishing intriguing energy‐driven cancer‐therapeutic modalities. This article is categorized under: Nanotechnology Approaches to Biology >Nanoscale Systems in Biology

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Ultrasmall BiOI Quantum Dots with Efficient Renal Clearance for Enhanced Radiotherapy of Cancer

Cited by 66 publications

References 50 publications

Reactive Oxygen Species‐Regulating Strategies Based on Nanomaterials for Disease Treatment

Reactive Oxygen Species‐Regulating Strategies Based on Nanomaterials for Disease Treatment

Palladium-based nanomaterials for cancer imaging and therapy

Energy‐converting biomaterials for cancer therapy: Category, efficiency, and biosafety

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