Targeted Gold Nanocluster‐Enhanced Radiotherapy of Prostate Cancer

Luo, Dong Hua; Wang, Xinning; Zeng, Sophia; Gopalakrishnan, Ramakrishnan; Burda, Clemens; Basilion, James P.

doi:10.1002/smll.201900968

Cited by 81 publications

(95 citation statements)

References 37 publications

(41 reference statements)

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“…The use of X-ray as the light source is most suitable for activating the Au NCs for deep-tissue cancer treatment and biomedical imaging applications, due to its nearly unlimited penetration depth in living tissues and organisms. An interesting review, 99,100 as well as various other recent publications [101][102][103] covering the applications of Au NCs as radiosensitizers are available.…”

Section: Basic Principle Of Photosensitization For Pdtmentioning

confidence: 99%

Photo/electrocatalysis and photosensitization using metal nanoclusters for green energy and medical applications

2020

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Section: Basic Principle Of Photosensitization For Pdtmentioning

confidence: 99%

Photo/electrocatalysis and photosensitization using metal nanoclusters for green energy and medical applications

2020

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“…While many efforts have been focused on the development of PSMA-targeted imaging and radionuclide therapy, there are few examples of small-molecule PSMA-targeted chemotherapeutics [ 37 , 38 , 39 , 40 ] and they all used 2-(3-(1,3-dicarboxypropyl)-ureido) pentanedioic acid (DUPA) to deliver the drugs, which has Ki = 8 nM to PSMA receptor [ 37 ]. We have previously developed a highly negatively charged PSMA ligand that has binding affinity 5-fold higher than the parent PSMA ligand, (S)-2-(3-((S)-5-amino-1-carboxypentyl)ureido) pentanedioic acid (ZJ24, Ki = 0.3 nM) [ 37 , 41 ], and have achieved excellent results with near-infrared agents, PDT agents, and gold nanoparticles with this negatively charged ligand [ 42 , 43 , 44 , 45 , 46 , 47 ]. In this study, we have exploited this higher-affinity ligand, PSMA-1 [ 43 ], to selectively deliver the very potent microtubule disruption drug, monomethyl auristatin E (MMAE), to prostate cancer cells.…”

Section: Introductionmentioning

confidence: 99%

Small Molecule-Based Prodrug Targeting Prostate Specific Membrane Antigen for the Treatment of Prostate Cancer

Wang

Shirke

Walker

et al. 2021

Cancers

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Metastatic castration-resistant prostate cancer poses a serious clinical problem with poor outcomes and remains a deadly disease. New targeted treatment options are urgently needed. PSMA is highly expressed in prostate cancer and has been an attractive biomarker for the treatment of prostate cancer. In this study, we explored the feasibility of targeted delivery of an antimitotic drug, monomethyl auristatin E (MMAE), to tumor tissue using a small-molecule based PSMA lig-and. With the aid of Cy5.5, we found that a cleavable linker is vital for the antitumor activity of the ligand–drug conjugate and have developed a new PSMA-targeting prodrug, PSMA-1-VcMMAE. In in vitro studies, PSMA-1-VcMMAE was 48-fold more potent in killing PSMA-positive PC3pip cells than killing PSMA-negative PC3flu cells. In in vivo studies, PSMA-1-VcMMAE significantly inhibited tumor growth leading to prolonged animal survival in different animal models, including metastatic prostate cancer models. Compared to anti-PSMA antibody-MMAE conjugate (PSMA-ADC) and MMAE, PSMA-1-VcMMAE had over a 10-fold improved maximum tolerated dose, resulting in improved therapeutic index. The small molecule–drug conjugates reported here can be easily synthesized and are more cost efficient than anti-body–drug conjugates. The therapeutic profile of the PSMA-1-VcMMAE encourages further clin-ical development for the treatment of advanced prostate cancer.

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“…As far as EBRT is concerned, the high intensities of radiation beam severely damage the surrounding healthy tissues. Vexatiously, tumor hypoxia could induce the seriously limited therapeutic outcomes (Luo et al, 2019; Sahu, Kwon, & Tae, 2020; Song, Cheng, Chao, Yang, & Liu, 2017; Wu et al, 2019). Herein, various radiation‐driven ROS‐ECBs with strong X‐ray attenuation ability have been discussed to find a reasonable optimization strategy for solving these underlying critical issues.…”

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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Targeted Gold Nanocluster‐Enhanced Radiotherapy of Prostate Cancer

Cited by 81 publications

References 37 publications

Photo/electrocatalysis and photosensitization using metal nanoclusters for green energy and medical applications

Photo/electrocatalysis and photosensitization using metal nanoclusters for green energy and medical applications

Small Molecule-Based Prodrug Targeting Prostate Specific Membrane Antigen for the Treatment of Prostate Cancer

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

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