One-Pot Self-Assembly of Core-Shell Nanoparticles within Fibers by Coaxial Electrospinning for Intestine-Targeted Delivery of Curcumin

Hou, Lijuan; Zhang, Laiming; Yu, Chengxiao; Chen, Jianle; Ye, Xingqian; Zhang, Fuming; Linhardt, Robert J.; Chen, Shiguo; Pan, Haibo

doi:10.3390/foods12081623

Cited by 6 publications

(5 citation statements)

References 60 publications

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“…This indicated that the ES100–CUR fibers improved the thermal stability of the EPO–RTV fibers in the form of bifibers. These findings align with previous research results and demonstrate the thermal decomposition behavior and thermal stability of the studied materials as characterized by TGA analysis. , …”

Section: Resultssupporting

confidence: 92%

Advanced 3D Electrospinning “Xspin” System: Fabrication of Bifiber Floating Oral Pharmaceutical Scaffolds for Controlled Drug Delivery

Darwesh,

Zhang,

Aghda

et al. 2024

Mol. Pharmaceutics

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Electrospinning has become a widely used and efficient method for manufacturing nanofibers from diverse polymers. This study introduces an advanced electrospinning technique, Xspin -a multi-functional 3D printing platform coupled with electrospinning system, integrating a customised 3D printhead, MaGIC -Multi-channeled and Guided Inner Controlling printheads. The Xspin system represents a cutting-edge fusion of electrospinning and 3D printing technologies within the realm of pharmaceutical sciences and biomaterials. This innovative platform excels in the production of novel fiber with various materials and allows for the creation of highly customized fiber structures, a capability hitherto unattainable through conventional electrospinning methodologies. By integrating the benefits of electrospinning with the precision of 3D printing, the Xspin system offers enhanced control over the scaffold morphology and drug release kinetics. Herein, we fabricated a model floating pharmaceutical dosage for the dual delivery of curcumin and ritonavir and thoroughly characterized the product. Fourier transform infrared (FTIR) spectroscopy demonstrated that curcumin chemically reacted with the polymer during the Xspin process. Thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) confirmed the solid-state properties of the active pharmaceutical ingredient after Xspin processing. Scanning electron microscopy (SEM) revealed the surface morphology of the Xspin-produced fibers, confirming the presence of the bifiber structure. To optimize the quality and diameter control of the electrospun fibers, a design of experiment (DoE) approach based on quality by design (QbD) principles was utilized. The bifibers expanded to approximately 10−11 times their original size after freeze-drying and effectively entrapped 87% curcumin and 84% ritonavir. In vitro release studies demonstrated that the Xspin system released 35% more ritonavir than traditional pharmaceutical pills in 2 h, with curcumin showing complete release in pH 1.2 in 5 min, simulating stomach media. Furthermore, the absorption rate of curcumin was controlled by the characteristics of the linked polymer, which enables both drugs to be absorbed at the desired time. Additionally, multivariate statistical analyses (ANOVA, pareto chart, etc.) were conducted to gain better insights and understanding of the results such as discern statistical differences among the studied groups. Overall, the Xspin system shows significant potential for manufacturing nanofiber pharmaceutical dosages with precise drug release capabilities, offering new opportunities for controlled drug delivery applications.

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Section: Resultssupporting

confidence: 92%

Advanced 3D Electrospinning “Xspin” System: Fabrication of Bifiber Floating Oral Pharmaceutical Scaffolds for Controlled Drug Delivery

Darwesh,

Zhang,

Aghda

et al. 2024

Mol. Pharmaceutics

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“…When combined with electrospinning nanotechnology, pH-sensitive materials offer an effective targeted drug delivery system that addresses issues such as nonspecific tissue distribution and facilitates efficient drug therapy. Colon-targeted drug delivery is a typical pH-sensitive drug delivery system, which overcomes the pH changes in the gastrointestinal tract to deliver drugs effectively (Hou et al, 2023). pH-sensitive polymers exhibited limited solubility in acidic environments, while they can dissolve under neutral or alkaline conditions.…”

Section: Colonmentioning

confidence: 99%

Electrospun multi‐chamber core–shell nanofibers and their controlled release behaviors: A review

Liu,

Chen,

Lin

et al. 2024

WIREs Nanomed Nanobiotechnol

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Core–shell structure is a concentric circle structure found in nature. The rapid development of electrospinning technology provides more approaches for the production of core–shell nanofibers. The nanoscale effects and expansive specific surface area of core–shell nanofibers can facilitate the dissolution of drugs. By employing ingenious structural designs and judicious polymer selection, specialized nanofiber drug delivery systems can be prepared to achieve controlled drug release. The synergistic combination of core–shell structure and materials exhibits a strong strategy for enhancing the drug utilization efficiency and customizing the release profile of drugs. Consequently, multi‐chamber core–shell nanofibers hold great promise for highly efficient disease treatment. However, little attention concentration is focused on the effect of multi‐chamber core–shell nanofibers on controlled release of drugs. In this review, we introduced different fabrication techniques for multi‐chamber core–shell nanostructures, including advanced electrospinning technologies and surface functionalization. Subsequently, we reviewed the different controlled drug release behaviors of multi‐chamber core–shell nanofibers and their potential needs for disease treatment. The comprehensive elucidation of controlled release behaviors based on electrospun multi‐chamber core–shell nanostructures could inspire the exploration of novel controlled delivery systems. Furthermore, once these fibers with customizable drug release profiles move toward industrial mass production, they will potentially promote the development of pharmacy and the treatment of various diseases.This article is categorized under: Therapeutic Approaches and Drug Discovery > Emerging Technologies

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“…Zein, as a plant-derived protein, has unique hydrophobic and hydrophilic regions that enable it to self-assemble into stable nanoparticles, which not only provides an ideal carrier for drug delivery systems but also opens up new avenues for the development of green, sustainable nanomaterials [ 10 ]. At present, the research on zein nanoparticles has been gradually transitioning from basic theoretical exploration to the practical application stage, including optimizing preparation processes, regulating hydrophilic and hydrophobic, improving stability and enhancing targeting [ 11 , 12 , 13 ]. However, there are still issues with how to accurately control the size and enhance the preparation efficiency of zein nanoparticles and dynamically adjust their hydrophilic and hydrophobic interface characteristics.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Regulation of Natural Amphiphilic Zein Nanoparticles by Microfluidic Technology

Liu,

Ma,

et al. 2024

Foods

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Microfluidic technology, as a continuous and mass preparation method of nanoparticles, has attracted much attention in recent years. In this study, zein nanoparticles (ZNPs) were continuously fabricated in a highly controlled manner by combining a microfluidics platform with the antisolvent method. The impact of ethanol content (60~95%, v/v) and flow rates of inner and outer phases in the microfluidics platform on particle properties were examined. Among all ZNPS, 90%-ZNPs have the highest solubility (32.83%) and the lowest hydrophobicity (90.43), which is the reverse point of the hydrophobicity of ZNPs. Moreover, when the inner phase flow rate was 1.5 mL/h, the particle size decreased significantly from 182.81 nm to 133.13 nm as the outer phase flow rate increased from 10 mL/h to 50 mL/h. The results revealed that ethanol content had significant impacts on hydrophilic–hydrophobic properties of ZNPs. The flow rates of ethanol–water solutions and deionized water (solvent and antisolvent) in the microfluidics platform significantly affected the particle size of ZNPs. These findings demonstrated that the combined application of a microfluidics platform and an antisolvent method could be an effective pathway for precisely controlling the fabrication process of protein nanoparticles and modulating their physicochemical properties.

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One-Pot Self-Assembly of Core-Shell Nanoparticles within Fibers by Coaxial Electrospinning for Intestine-Targeted Delivery of Curcumin

Cited by 6 publications

References 60 publications

Advanced 3D Electrospinning “Xspin” System: Fabrication of Bifiber Floating Oral Pharmaceutical Scaffolds for Controlled Drug Delivery

Advanced 3D Electrospinning “Xspin” System: Fabrication of Bifiber Floating Oral Pharmaceutical Scaffolds for Controlled Drug Delivery

Electrospun multi‐chamber core–shell nanofibers and their controlled release behaviors: A review

Preparation and Regulation of Natural Amphiphilic Zein Nanoparticles by Microfluidic Technology

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