Gas-Mediated Cancer Bioimaging and Therapy

Chen, Lichan; Zhou, Shu‐Feng; Su, Lichao; Song, Jibin

doi:10.1021/acsnano.9b04954

Cited by 237 publications

(154 citation statements)

References 299 publications

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“…[13][14][15][16] On the other hand, CO is also believed to be of anticancer activity. [17][18][19] Therefore, exploring the medical potentials of CO have been one of the active research areas. [15][16][17][18][19][20][21] One of the actively researched areas is how safe and controllable to deliver CO. Its administration via direct inhalation is certainly the easiest and simplest approach; however, its shortcoming is obvious because of its lacking specificity and safety concern.…”

Section: Introductionmentioning

confidence: 99%

“…[17][18][19] Therefore, exploring the medical potentials of CO have been one of the active research areas. [15][16][17][18][19][20][21] One of the actively researched areas is how safe and controllable to deliver CO. Its administration via direct inhalation is certainly the easiest and simplest approach; however, its shortcoming is obvious because of its lacking specificity and safety concern. To deliver CO effectively, safely, and controllably in clinic applications, the concept of CO-releasing molecules (CORMs), either organic compounds or transition metal carbonyls, was proposed in the beginning of this century by Motterlini et al [22] The CORMs release CO under external stimulations such as ligand exchange reaction, photon-induction, redox initiation, enzymatic triggering, and thermal decomposition.…”

Section: Introductionmentioning

confidence: 99%

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Four iron(II) carbonyl complexes containing both pyridyl and halide ligands: Their synthesis, characterization, stability, and anticancer activity

Guo

Jin

Xiao

et al. 2020

Applied Organom Chemis

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Four iron(II) carbonyl complexes, fac-[Fe (CO) 3 X 2 (py)] (X = I − , 1 and Br − , 3), fac-[{Fe (CO) 3 X 2 } 2 (bipy)] (X = I − , 2 and Br − , 4), were facilely synthesized by reacting cis-[Fe (CO) 4 X 2 ] (X = I − , Br −) with pyridine (py) and 4,4 0-dipyridine (bipy) ligands, respectively, in good yields (70%85%). These complexes were fully characterized, and the structures of Complexes 2 and 3 were crystallographically analyzed. In dimethyl sulfoxide, they decomposed rapidly to release carbon monoxide (CO), and in methanol, they showed better stability which allowed kinetically analyzing their decomposing behaviors. The selfdecomposing in methanol fitted first-order kinetics with a half-time ranging from several minutes to 1 h. Our results suggested that the ligand with great conjugation (bipy) and strong electron-donating capability (iodide) could stabilize the iron(II) carbonyl complexes. The decomposition of the iodo complexes (1 and 2) involved the production of iodine radicals. MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide) assessments revealed that the efficacy against human bladder carcinoma cell line (RT112) is in the following trend: 1 > 2 > 3 > 4. The relatively strong efficacy of Complexes 1 and 2 is mainly contributed to the in situ generated iodine radicals. The combination of the cytotoxicity of the in situ generated radicals with the anticancer activity of CO as reported in literatures may lead to developing novel anticancer drugs with enhanced efficacy. K E Y W O R D S anticancer activity, carbon monoxide release and kinetics, iodine radical, iron carbonyl compounds, solvolysis Zhuming Guo and Jing Jin contributed equally to this work.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Four iron(II) carbonyl complexes containing both pyridyl and halide ligands: Their synthesis, characterization, stability, and anticancer activity

Guo

Jin

Xiao

et al. 2020

Applied Organom Chemis

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“…Take chemotherapeutic drugs for tumor treatment as an example. Chemotherapy usually suffers from drug resistance in cancer therapy, whereas gaseous CO molecules do not induce drug resistance because it can easily diffuse into the tumor tissue and lead to cell apoptosis following CO‐responsive metabolic exhaustion . Furthermore, CO could not only amplify tumor cell death when treated in combination with chemotherapeutic drugs but also exert cytoprotective function and protect normal cells against chemotherapeutic agent‐induced cell toxicity .…”

Section: Introductionmentioning

confidence: 99%

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Yan

Zhu

et al. 2019

Small

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Carbon monoxide (CO) therapy has emerged as a hot topic under exploration in the field of gas therapy as it shows the promise of treating various diseases. Due to the gaseous property and the high affinity for human hemoglobin, the main challenges of administrating medicinal CO are the lack of target selectivity as well as the toxic profile at relatively high concentrations. Although abundant CO releasing molecules (CORMs) with the capacity to deliver CO in biological systems have been developed, several disadvantages related to CORMs, including random diffusion, poor solubility, potential toxicity, and lack of on‐demand CO release in deep tissue, still confine their practical use. Recently, the advent of versatile nanomedicine has provided a promising chance for improving the properties of naked CORMs and simultaneously realizing the therapeutic applications of CO. This review presents a brief summarization of the emerging delivery strategies of CO based on nanomaterials for therapeutic application. First, an introduction covering the therapeutic roles of CO and several frequently used CORMs is provided. Then, recent advancements in the synthesis and application of versatile CO releasing nanomaterials are elaborated. Finally, the current challenges and future directions of these important delivery strategies are proposed.

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“…H 2 can selectively scavenge reactive oxygen species, especially hydroxyl radicals (•OH) and peroxynitrite anions (ONOO - ) without influence on normal metabolic oxidation/reduction reactions or cell signal transduction. In addition to tumor therapy, potential applications in anti-oxidant, anti-inflammatory, and anti-apoptotic scenarios have been studied 101 - 103 . Compared with chemotherapeutic drugs, H 2 can easily penetrate biological membranes and diffuse in tissues and cells.…”

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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Gas-Mediated Cancer Bioimaging and Therapy

Cited by 237 publications

References 299 publications

Four iron(II) carbonyl complexes containing both pyridyl and halide ligands: Their synthesis, characterization, stability, and anticancer activity

Four iron(II) carbonyl complexes containing both pyridyl and halide ligands: Their synthesis, characterization, stability, and anticancer activity

Emerging Delivery Strategies of Carbon Monoxide for Therapeutic Applications: from CO Gas to CO Releasing Nanomaterials

Palladium-based nanomaterials for cancer imaging and therapy

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