Innovative Multilayer Electrospun Patches for the Slow Release of Natural Oily Extracts as Dressings to Boost Wound Healing

Fiaschini, Noemi; Carnevali, Fiorella; Van der Esch, Stephen Andrew; Vitali, Roberta; Mancuso, Mariateresa; Sulli, Maria; Diretto, Gianfranco; Negroni, Anna; Rinaldi, Antonio

doi:10.3390/pharmaceutics16020159

Pharmaceutics

2024

DOI: 10.3390/pharmaceutics16020159

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Innovative Multilayer Electrospun Patches for the Slow Release of Natural Oily Extracts as Dressings to Boost Wound Healing

Noemi Fiaschini,

Fiorella Carnevali,

Stephen Andrew Van der Esch

et al.

Abstract: Electrospinning is an advanced manufacturing strategy used to create innovative medical devices from continuous nanoscale fibers that is endowed with tunable biological, chemical, and physical properties. Innovative medical patches manufactured entirely by electrospinning are discussed in this paper, using a specific plant-derived formulation “1 Primary Wound Dressing©” (1-PWD) as an active pharmaceutical ingredient (API). 1-PWD is composed of neem oil (Azadirachta indica A. Juss.) and the oily extracts of Hyp… Show more

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Cited by 3 publications

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Industrial-scale needle-less electrospinning of tetracycline-immobilized nanofibrous scaffolds using a polycaprolactone/polyethylene oxide/chitosan blend for wound healing

Lubasova,

Tomankova,

Polakova

2024

Journal of Industrial Textiles

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Nanofibrous scaffolds offer significant promise for wound healing due to their ability to absorb exudates, prevent microbial contamination, and enhance oxygen diffusion. However, challenges remain in fully realizing their clinical potential, as previous research has primarily focused on scaffolds made of two polymers or those encapsulating therapeutic agents within nanofibers. Additionally, scaling up fabrication while maintaining functionality presents a significant challenge. This study introduces a novel type of nanofibrous scaffold, combining poly (ethylene oxide) (PEO), poly (caprolactone) (PCL), and chitosan (CS) in various mass ratios, electrospun using Nanospider™ technology. The scaffolds featured fiber diameters ranging from 134 ± 37 to 148 ± 38 nm and exhibit high gram-per-square-meter values between 6.8 and 8.6 g/m2. An optimal balance of hydrophilicity was achieved, and the scaffolds demonstrated superior breathability with moisture vapor transmission rates ranging from 1904.3 ± 28.6 to 2005.7 ± 42.9 g/m2/day, outperforming commercial wound dressings. Additionally, a wide range of hydrolytic degradation rates (3.8 ± 1% to 73.2 ± 0.8%), elongation at fracture (21% to 0.8%), and Young’s modulus (106.7 ± 8.5 MPa to 170.7 ± 11.9 MPa) were observed. Surface-immobilized tetracycline (TET) significantly enhanced antibacterial efficacy, with inhibition zones exceeding 20 mm against Escherichia coli. Our findings confirm that scaffold properties can be effectively tailored by adjusting the PEO/PCL ratio, advancing customization for wound care. Post-fabrication soaking in TET solutions further boosts antibacterial performance and allows for tailored post-production adjustments. Compared to existing studies, this approach simplifies customization and improves the practicality of wound care solutions.

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Industrial-scale needle-less electrospinning of tetracycline-immobilized nanofibrous scaffolds using a polycaprolactone/polyethylene oxide/chitosan blend for wound healing

Lubasova,

Tomankova,

Polakova

2024

Journal of Industrial Textiles

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Alginate-Based Electrospun Nanofibers and the Enabled Drug Controlled Release Profiles: A Review

Zhang,

Liu,

et al. 2024

Biomolecules

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Alginate is a natural polymer with good biocompatible properties and is a potential polymeric material for the sustainable development and replacement of petroleum derivatives. However, the non-spinnability of pure alginate solutions has hindered the expansion of alginate applications. With the continuous development of electrospinning technology, synthetic polymers, such as PEO and PVA, are used as co-spinning agents to increase the spinnability of alginate. Moreover, the coaxial, parallel Janus, tertiary and other diverse and novel electrospun fiber structures prepared by multi-fluid electrospinning have found a new breakthrough for the problem of poor spinning of natural polymers. Meanwhile, the diverse electrospun fiber structures effectively achieve multiple release modes of drugs. The powerful combination of alginate and electrostatic spinning is widely used in many biomedical fields, such as tissue engineering, regenerative engineering, bioscaffolds, and drug delivery, and the research fever continues to climb. This is particularly true for the controlled delivery aspect of drugs. This review provides a brief overview of alginate, introduces new advances in electrostatic spinning, and highlights the research progress of alginate-based electrospun nanofibers in achieving various controlled release modes, such as pulsed release, sustained release, biphasic release, responsive release, and targeted release.

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Advances in Electrospun Poly(ε-caprolactone)-Based Nanofibrous Scaffolds for Tissue Engineering

Robles,

Zahra,

et al. 2024

Polymers

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Tissue engineering has great potential for the restoration of damaged tissue due to injury or disease. During tissue development, scaffolds provide structural support for cell growth. To grow healthy tissue, the principal components of such scaffolds must be biocompatible and nontoxic. Poly(ε-caprolactone) (PCL) is a biopolymer that has been used as a key component of composite scaffolds for tissue engineering applications due to its mechanical strength and biodegradability. However, PCL alone can have low cell adherence and wettability. Blends of biomaterials can be incorporated to achieve synergistic scaffold properties for tissue engineering. Electrospun PCL-based scaffolds consist of single or blended-composition nanofibers and nanofibers with multi-layered internal architectures (i.e., core-shell nanofibers or multi-layered nanofibers). Nanofiber diameter, composition, and mechanical properties, biocompatibility, and drug-loading capacity are among the tunable properties of electrospun PCL-based scaffolds. Scaffold properties including wettability, mechanical strength, and biocompatibility have been further enhanced with scaffold layering, surface modification, and coating techniques. In this article, we review nanofibrous electrospun PCL-based scaffold fabrication and the applications of PCL-based scaffolds in tissue engineering as reported in the recent literature.

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Innovative Multilayer Electrospun Patches for the Slow Release of Natural Oily Extracts as Dressings to Boost Wound Healing

Cited by 3 publications

References 33 publications

Industrial-scale needle-less electrospinning of tetracycline-immobilized nanofibrous scaffolds using a polycaprolactone/polyethylene oxide/chitosan blend for wound healing

Industrial-scale needle-less electrospinning of tetracycline-immobilized nanofibrous scaffolds using a polycaprolactone/polyethylene oxide/chitosan blend for wound healing

Alginate-Based Electrospun Nanofibers and the Enabled Drug Controlled Release Profiles: A Review

Advances in Electrospun Poly(ε-caprolactone)-Based Nanofibrous Scaffolds for Tissue Engineering

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