Formation of He-Rich Layers Observed by Neutron Reflectometry in the He-Ion-Irradiated Cr/W Multilayers: Effects of Cr/W Interfaces on the He-Trapping Behavior

Chen, Feida; Tang, Xiaobin; Huang, Hai; Li, Xinxi; Yan, Wei; Huang, Congcong; Liu, Jian; Li, Huan; Chen, Da

doi:10.1021/acsami.6b07419

Cited by 34 publications

(40 citation statements)

References 26 publications

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“…MoSe 2 nanodots were biocompatible in vitro at concentrations up to 160 µg mL −1 and exhibited better photostability than ICG. In vitro PTT [203] Copyright 2017, American Chemical Society. application of these MoSe 2 nanodots was demonstrated in HeLa cells incubated with 40 µg mL −1 MoSe 2 and treated with 2 W cm −2 , 785 nm light irradiation, displaying pronounced effect as cell viability of less than 8% was achieved.…”

Section: Photothermal Therapymentioning

confidence: 99%

“…In a study by Chen et al, photother-mal application of MoS 2 nanosheets with degradable property was reported. [203] MoS 2 -PAA was synthesized by hydrothermal reaction of ammonium molybdate tetrahydrate and PAA, and subsequently functionalized with PEG-amine to produce MoS 2 -PPEG (Figure 21A). After 5 min of 1 W cm −2 808 nm light irradiation, temperature of 200 µg mL −1 MoS 2 -PPEG solution rose from 25.8 to 51.4°C.…”

Section: Photothermal Therapymentioning

confidence: 99%

“…The small VS 2 @lipid-PEG were observed to prefer fecal clearance in vivo, contrary to previously reported renal pathway in degradable MoS 2 . [203]…”

Section: Photothermal Therapymentioning

confidence: 99%

“…WS 2 LA-PEG PTT 20 mg kg −1 808 0.8 5 35°C - [189] MoS 2 PEG PTT 200 µg Mo 808 1 5 -- [197] MoS 2 LA-PEG PTT 8 µg 808 1 15 -27.6 [201] MoS 2 Polyacrylic acidLA-PEG PTT 50 µg 808 1 10 Reached 52.1°C - [203] VS 2 PEGDOPA PTT 20 mg kg −1 808 0.6 5 Reached 58°C 31.5 [206] MoS 2 DMSA-IONPLA-PEG PTT 6.85 mg kg −1 808 0.78 5 Reached 51°C - [211] MoS 2 Fe 3 O 4 PEG PTT 100 µg 808 1 12 22°C 43.93 [213] WS 2 C 18 PMH-PEGGd 3+ PTT/RT 20 mg kg −1 808 0.54 Gy (RT) 103 (RT) Reached 47°C - [198] WS ReS 2 C 18 PMH-PEG PTT/RT 20 mg kg −1 808 0.6 20 Reached 45°C - [219] MoS 2 LA-PEGDOX PTT/DDS 3.4 mg kg −1 808 0.56 20 Reached 45°C - [191] MoS 2 ChitosanDOX PTT/DDS 2 mg kg −1 808 0.9 7 22.5°C 24.37 [187] MoS 2 BSARV PTT/DDS 2 mg kg −1 808 1 5 -- [192] MoSe 2 PolydopamineDOX PTT/DDS 0.1 mg mL −1 808 2 5 -44.5 [221] WS 2 IONP, MS, C 18 PMH-PEGDOX PTT/DDS 8.4 mg mL −1 808 0.55 10 15°C - [222] MoS 2 PEI-HADOXNOTA-64 Cu PTT/DDS 200 µL 808 0.6 10 -- [224] MoS 2 PLGA oleosolDOX PTT/DDS 75 µg MoS 2 808 0.6 5 Reached 56.5°C - [225] MoS 2 Gen 5-PAMAM PTT/GDS 0.1 mg 808 1.2 5 Reached 60.2°C 47.8 [230] MoS 2 LA-PEGCe6 PTT/PDT 6.85 mg kg −1 808600 (PDT) 0.455 × 10 −3 (PDT) 20…”

Section: Metal Oxidesmentioning

confidence: 99%

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Advanced Near‐Infrared Light‐Responsive Nanomaterials as Therapeutic Platforms for Cancer Therapy

Chien

Chan

Anderson

et al. 2018

Advanced Therapeutics

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Cancer is one of the leading causes of death. Despite the huge progress in the field of cancer drugs and therapies, the treatment outcome is still bleak for most cancer patients. Nanotechnology has revolutionized cancer therapeutics. By using nano-sized particles as delivery systems, therapeutic biomolecules are transported efficiently to the target sites. Moreover, these particles are designed to carry out multiple cancer treatments simultaneously. Near-infrared (NIR) light-responsive nanomaterials have gained much attention as NIR light has a greater penetration depth, minimal phototoxicity, lower autofluorescence, and reduced light scattering. Among the available NIR light-responsive nanomaterials, gold nanorods, upconversion nanoparticles, carbon dots, transition metal dichalcogenide, metal oxides, black phosphorus, and polymeric nanomaterials have become attractive options owing to their excellent optical properties, ease of synthesis and modification, outstanding photodynamic and photothermal conversion properties, and most importantly, favorable toxicity level and biocompatibility which are prerequisites for biological applications. In this review, the outstanding properties, synthesis, and surface functionalization of the aforementioned NIR light-responsive nanomaterials are introduced in detail. Recent advances of these nanomaterials for various cancer treatment modalities are summarized to highlight their versatility and potential in cancer theranostics. Finally, a perspective is proposed on future research directions and their clinical translation.

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Section: Photothermal Therapymentioning

confidence: 99%

Section: Photothermal Therapymentioning

confidence: 99%

“…The small VS 2 @lipid-PEG were observed to prefer fecal clearance in vivo, contrary to previously reported renal pathway in degradable MoS 2 . [203]…”

Section: Photothermal Therapymentioning

confidence: 99%

Section: Metal Oxidesmentioning

confidence: 99%

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Advanced Near‐Infrared Light‐Responsive Nanomaterials as Therapeutic Platforms for Cancer Therapy

Chien

Chan

Anderson

et al. 2018

Advanced Therapeutics

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“…[34] They found that these LA-PEG-modified TMDC materials all exhibit desirable compatibility in a physiological environment with additional excellent biomedical applications, such as multimodal imaging and synergistic therapy for cancer treatment. In addition to PEG, other polymers such as poly(acrylic acid) (PAA), [143] polyethylenimine (PEI), [144] combined PAA-PEG [145] or PEI-PEG, [131,146] or polyaniline (PANI), [130] as well as generation-5 poly(amidoamine) dendrimers-lipoic acid (G5-LA) [147] are also widely used in the process for functionalization of TMDCs. For example, similar to LA-PEG functionalization, effective polymer conjugation via the disulfide bond was reported by Kim et al, in which MoS 2 was modified with LA-modified PEI, as well as thiolated PEG polymers (MoS 2 -PEI-PEG) (Figure 9a).…”

Section: Polymersmentioning

confidence: 99%

Design, Synthesis, and Surface Modification of Materials Based on Transition‐Metal Dichalcogenides for Biomedical Applications

et al. 2017

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With the rapid development of nanotechnology, the emerging transition‐metal dichalcogenides (TMDCs) have become one of the most promising inorganic nanomaterials for medical applications due to their distinctive structures and properties. TMDCs with different sizes and morphologies exhibit unique structural advantages, as well as versatile properties. However, concerning their practicability for biomedical applications, routes toward their synthesis and chemical/physical functionalization for biosystem applications must be identified. Herein, recent advances in the design, synthesis, and surface modification of TMDC‐based nanomaterials specific for biomedical applications are reviewed. First, the basic consideration regarding how to fabricate biocompatible TMDCs efficiently for biomedical use is discussed. Solution‐based synthesis methods for 2D TMDCs, as well as TMDC‐based nanocomposites are then summarized. In addition, general strategies applied for surface functionalization of TMDCs are also discussed. Finally, current challenges and future perspectives for these promising materials in biosystem applications are outlined.

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Nanostructured Spinel Manganates and Their Composites for Electrochemical Energy Conversion and Storage

Rani

Sivanantham

Cho

2023

Adv Funct Materials

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Spinel manganates (AMn2O4; A = Co, Ni, Cu, Zn, and Fe; collectively referred to as AMO) are promising electrode materials for water electrolyzers, pseudocapacitors, and batteries owing to their inherent advantages such as valence variability, high catalytic activity, conductivity, stability, low‐cost, and environmental friendliness. Nanostructured materials, with a large surface area and short ion diffusion length, offer great potential for achieving enhanced electrochemical performance. This review summarizes spinel manganates with various nanostructured morphologies and discusses the impact of the structure and composition on the electrochemical performance. The review demonstrates that nanostructured spinel manganates with preferred A‐site cation significantly improve the thermodynamics and electrochemical reaction kinetics at solid–liquid and solid–solid interfaces. Notably, faceted, hollow, 1D nanostructured CoMn2O4 and its nanocomposites (CoMn/CoMn2O4 and NiMn2O4/C) exhibit outstanding electrochemical performance. The review also provides an overview of the importance of energy conversion and storage, and the advantages of spinel manganates as electrode materials. Additionally, the review describes feasible methods of synthesizing AMO nanostructures and nanocomposites. The insights provided in this review are expected to contribute to the synthesis of spinel manganates with desired morphologies and compositions, enabling the future development of efficient electrode materials for energy conversion and storage devices.

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Formation of He-Rich Layers Observed by Neutron Reflectometry in the He-Ion-Irradiated Cr/W Multilayers: Effects of Cr/W Interfaces on the He-Trapping Behavior

Cited by 34 publications

References 26 publications

Advanced Near‐Infrared Light‐Responsive Nanomaterials as Therapeutic Platforms for Cancer Therapy

Advanced Near‐Infrared Light‐Responsive Nanomaterials as Therapeutic Platforms for Cancer Therapy

Design, Synthesis, and Surface Modification of Materials Based on Transition‐Metal Dichalcogenides for Biomedical Applications

Nanostructured Spinel Manganates and Their Composites for Electrochemical Energy Conversion and Storage

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