Functional nanoparticles in electrospun fibers for biomedical applications

Saiding, Qimanguli; Cui, Wenguo

doi:10.1002/nano.202100335

Cited by 14 publications

(14 citation statements)

References 123 publications

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“…By incorporating immunoregulative components into electrospun fibers, one can effectively extend the releasing duration, exerting a continuous immunoregulative impact on the surrounding microenvironment and facilitating tissue regeneration. 118,119 Oral lichen planus is a T-cell-mediated autoimmune disorder that can be treated with topical corticosteroid mouthwashes or sprays. 120 Given this, Said et al fabricated glucocorticoid clobetasol-17-propionate-loaded PVP electrospun fibers to extend the localized immunoregulative effect of corticosteroids to suppress T-cell activation and IL-2 production, thus aiding in successful disease control.…”

Section: Immunoregulative Drug Loadingmentioning

confidence: 99%

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Electrospun fiber‐based immune engineering in regenerative medicine

Xu,

Saiding,

Zhou

et al. 2024

Smart Medicine

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Immune engineering, a burgeoning field within regenerative medicine, involves a spectrum of strategies to optimize the intricate interplay between tissue regenerative biomaterials and the host tissue. These strategies are applied across different types of biomaterials and various disease models, which encompasses finely modulating the immune response at the levels of immune cells and factors, aiming to mitigate adverse effects like fibrosis and persistent inflammation that may arise at the injury site and consequently promote tissue regeneration. With the continuous progress in electrospinning technology, the immunoregulatory capabilities of electrospun fibers have gained substantial attention over the years. Electrospun fibers, with their extracellular matrix‐like characteristics, high surface‐area‐to‐volume ratio, and reliable pharmaceutical compound capacity, have emerged as key players among tissue engineering materials. This review specifically focuses on the role of electrospun fiber‐based immune engineering, emphasizing their unique design strategies. Notably, electrospinning actively engages in immune engineering by modulating immune responses through four essential strategies: (i) surface modification, (ii) drug loading, (iii) physicochemical parameters, and (iv) biological grafting. This review presents a comprehensive overview of the intricate mechanisms of the immune system in injured tissues while unveiling the key strategies adopted by electrospun fibers to orchestrate immune regulation. Furthermore, the review explores the current developmental trends and limitations concerning the immunoregulatory function of electrospun fibers, aiming to drive the advancements in electrospun fiber‐based immune engineering to its full potential.

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Section: Immunoregulative Drug Loadingmentioning

confidence: 99%

Section: Electrospun Fiber‐based Immune Engineering Approachesmentioning

confidence: 99%

Electrospun fiber‐based immune engineering in regenerative medicine

Xu,

Saiding,

Zhou

et al. 2024

Smart Medicine

Self Cite

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“…The use of a polymer with pH-selective dissolution as the sheath of these fibers ensured the delivery in the duodenum [ 70 ]. Saiding and Cui [ 71 ] have systematically reviewed some recent hybrid platforms composed of electrospun nanofibers containing different nanoparticles for biomedical applications. Other supramolecular systems, such as micelles, vesicles or liposomes, dendrimers, nanogels, etc., are often used to increase the drug accumulation [ 72 ].…”

Section: Immobilization Of Supramolecular Structures Within/onto Elec...mentioning

confidence: 99%

Electrohydrodynamic Techniques for the Manufacture and/or Immobilization of Vesicles

et al. 2023

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The development of accurate drug delivery systems is one of the main challenges in the biomedical field. A huge variety of structures, such as vesicles, nanoparticles, and nanofibers, have been proposed as carriers for bioactive agents, aiming for precision in administration and dosage, safety, and bioavailability. This review covers the use of electrohydrodynamic techniques both for the immobilization and for the synthesis of vesicles in a non-conventional way. The state of the art discusses the most recent advances in this field as well as the advantages and limitations of electrospun and electrosprayed amphiphilic structures as precursor templates for the in situ vesicle self-assembly. Finally, the perspectives and challenges of combined strategies for the development of advanced structures for the delivery of bioactive agents are analyzed.

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“…Silica-based optical fibers are widely employed in optical communication, medical procedures, and sensing due to their low attenuation at infrared (IR) telecom wavelengths [1][2][3]. A vital application scenario is their integration in severe environments distinguished by ionizing or non-ionizing radiation, for example, those encountered in fusion/fission-related facilities, high energy physics facilities, and space missions [4,5].…”

Section: Introductionmentioning

confidence: 99%

Influence of temperature on the total ionizing dose effects in Al2O3-doped optical fibers

Ma,

He,

Lei

et al. 2024

Advanced Fiber Laser Conference (AFL2023)

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This article investigates the influence of temperature on the total ionizing dose (TID) effects in optical fibers.Radiation induced attenuation (RIA) spectra at 1310 nm were measured in G652, OM, PM1016-C, and homemade B1-R fibers during and after γ-irradiation at different temperatures. The B1-R fibers were doped with varying Al 2 O 3 content in their core and coating layers. Experimental results show that the B1-R fibers have significant lower losses compared with the other three fibers. At a temperature of 25° and a TID does of 50 kGy, the B1-R fiber showed an RIA of only 1.35 dB/Km, while the other three fibers exhibit a minimum loss exceeding 6.44 dB/Km. Furthermore, the B1-R fiber withstood an irradiation does 100 times higher than other optical fibers. For a fixed temperature, the attenuation in B1-R fibers recovered quickly after irradiation, reaching their minimum values approximately 15 days post-irradiation, whereas the other three optical fibers required more than 25 days to recover. This study also delves into the underlying mechanisms contributing to the radiation resistance of B1-R optical fibers. The findings presented in this work offer critical insights for the development of high-performance, radiation resistant fibers, rendering them suitable for deployment in challenging deep space environments characterized by intense radiation conditions.

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Functional nanoparticles in electrospun fibers for biomedical applications

Cited by 14 publications

References 123 publications

Electrospun fiber‐based immune engineering in regenerative medicine

Electrospun fiber‐based immune engineering in regenerative medicine

Electrohydrodynamic Techniques for the Manufacture and/or Immobilization of Vesicles

Influence of temperature on the total ionizing dose effects in Al2O3-doped optical fibers

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