Molecular Interactions in Electrospinning: From Polymer Mixtures to Supramolecular Assemblies

Ewaldz, Elena; Brettmann, Blair

doi:10.1021/acsapm.8b00073

Cited by 72 publications

(75 citation statements)

References 95 publications

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“…As previously reported 31,32 , during single-needle electrospray, molecular weight of the solution influences the jetting status as shown in Equation 3:…”

Section: 2effect Of Molecular Weight Of Shell Solution On Jet Flow and Particle Formationmentioning

confidence: 73%

Microparticle Formation via Tri-needle Coaxial Electrospray at Stable Jetting Modes

Yao

Zhang

Ahmad

et al. 2020

Ind. Eng. Chem. Res.

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Multi-layered structured organic particles have had an extensive impact on a wide array of biomedical applications not limited to drug delivery, imaging and biosensing. A trineedle coaxial electrospraying system was utilized to engineer multi-layered polymeric particles in a one-step, facile process at ambient temperatures. The effect of the dominant processing parameters on the development of a conical cusp that eventually ejects an ultrathin liquid ligament were firstly explored here. Subsequently, the validation of the intermediate solutions that possessed different conductivities on stabilizing jetting modes and the resulting particle morphology was also investigated.Polycaprolactone (PCL) solutions with different molecular weights were selected as the outer layer using fluids with various conductivities. Five different formulations were studied as the intermediate layers: PCL in acetic acid, ethyl cellulose in acetic acid, ethyl cellulose in dichloromethane, ethyl cellulose in ethanol and silicone oil and polyvinyl pyrrolidone in water. The results systematically demonstrated that the processing parameters (type of polymer, polymer molecular weight, solution concentration, flow rate, applied voltage and collector distance) play a significant role in the formation of the stable Taylor cone. This study further identified that the coaxial arrangement of three needles successfully produced multi-layered microspheres with uniform size distribution.

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“…As previously reported 31,32 , during single-needle electrospray, molecular weight of the solution influences the jetting status as shown in Equation 3:…”

Section: 2effect Of Molecular Weight Of Shell Solution On Jet Flow and Particle Formationmentioning

confidence: 73%

Microparticle Formation via Tri-needle Coaxial Electrospray at Stable Jetting Modes

Yao

Zhang

Ahmad

et al. 2020

Ind. Eng. Chem. Res.

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“…Furthermore, other critical factors that cause a polymeric solution to be subjected to the process of ellectrospinning in order to form eNFs are the molecular interactions: Polymer–polymer conjunction, polymer-small molecules (nanoparticles, additives, or salts, etc. ), and supramolecular polymers-small molecules [ 139 ]. The process of electrospinning gums with high molecular weight is demanding as a consequence of their heterogeneity, polydispersity, and abounding functional groups such as –NH 2 , –CO, –OH, –COOH, etc.…”

Section: Electrospun Nanofibers In Wound Healingmentioning

confidence: 99%

An Overview of Biopolymeric Electrospun Nanofibers Based on Polysaccharides for Wound Healing Management

et al. 2020

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Currently, despite the thoroughgoing scientific research carried out in the area of wound healing management, the treatment of skin injuries, regardless of etiology remains a big provocation for health care professionals. An optimal wound dressing should be nontoxic, non-adherent, non-allergenic, should also maintain a humid medium at the wound interfacing, and be easily removed without trauma. For the development of functional and bioactive dressings, they must meet different conditions such as: The ability to remove excess exudates, to allow gaseous interchange, to behave as a barrier to microbes and to external physical or chemical aggressions, and at the same time to have the capacity of promoting the process of healing by stimulating other intricate processes such as differentiation, cell adhesion, and proliferation. Over the past several years, various types of wound dressings including hydrogels, hydrocolloids, films, foams, sponges, and micro/nanofibers have been formulated, and among them, the electrospun nanofibrous mats received an increased interest from researchers due to the numerous advantages and their intrinsic properties. The drug-embedded nanofibers are the potential candidates for wound dressing application by virtue of: Superior surface area-to volume ratio, enormous porosity (can allow oxy-permeability) or reticular nano-porosity (can inhibit the microorganisms’adhesion), structural similitude to the skin extracellular matrix, and progressive electrospinning methodology, which promotes a prolonged drug release. The reason that we chose to review the formulation of electrospun nanofibers based on polysaccharides as dressings useful in wound healing was based on the ever-growing research in this field, research that highlighted many advantages of the nanofibrillary network, but also a marked versatility in terms of numerous active substances that can be incorporated for rapid and infection-free tissue regeneration. In this review, we have extensively discussed the recent advancements performed on electrospun nanofibers (eNFs) formulation methodology as wound dressings, and we focused as well on the entrapment of different active biomolecules that have been incorporated on polysaccharides-based nanofibers, highlighting those bioagents capable of improving the healing process. In addition, in vivo tests performed to support their increased efficacy were also listed, and the advantages of the polysaccharide nanofiber-based wound dressings compared to the traditional ones were emphasized.

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“…Another issue affecting the polymer–solution interactions is the tendency of some of the materials to assemble into the larger aggregates or to form chemical interactions with different components of the solution. Chemical interactions that take place in the solution, both those that occur spontaneously and those that are intentionally introduced, have been extensively evaluated and described in a recent study by Elena Ewaldz and Blair Brettmann [ 20 ]. The polymers that tend to form such interactions do not obey typical laws established for the ES—for example, the thickness of the fibers cannot be strictly controlled, the gelling can occur or generally non-spinnable solutions can become spinnable.…”

Section: Electrospinning—a Versatile Technique For Fibrous Materials Manufacturingmentioning

confidence: 99%

“…The polymers that tend to form such interactions do not obey typical laws established for the ES—for example, the thickness of the fibers cannot be strictly controlled, the gelling can occur or generally non-spinnable solutions can become spinnable. One example of naturally occurring self-assembling biopolymers are phospholipids [ 21 ], but this phenomenon is also observed in cyclodextrins or tannic acid [ 20 ]. It is worth noting that knowledge about self-assembly can be harvested for designing the materials to meet the specific needs.…”

Section: Electrospinning—a Versatile Technique For Fibrous Materials Manufacturingmentioning

confidence: 99%

Advances in Fabricating the Electrospun Biopolymer-Based Biomaterials

Wilk

Benko

2021

JFB

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Biopolymers formed into a fibrous morphology through electrospinning are of increasing interest in the field of biomedicine due to their intrinsic biocompatibility and biodegradability and their ability to be biomimetic to various fibrous structures present in animal tissues. However, their mechanical properties are often unsatisfactory and their processing may be troublesome. Thus, extensive research interest is focused on improving these qualities. This review article presents the selection of the recent advances in techniques aimed to improve the electrospinnability of various biopolymers (polysaccharides, polynucleotides, peptides, and phospholipids). The electrospinning of single materials, and the variety of co-polymers, with and without additives, is covered. Additionally, various crosslinking strategies are presented. Examples of cytocompatibility, biocompatibility, and antimicrobial properties are analyzed. Special attention is given to whey protein isolate as an example of a novel, promising, green material with good potential in the field of biomedicine. This review ends with a brief summary and outlook for the biomedical applicability of electrospinnable biopolymers.

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Molecular Interactions in Electrospinning: From Polymer Mixtures to Supramolecular Assemblies

Cited by 72 publications

References 95 publications

Microparticle Formation via Tri-needle Coaxial Electrospray at Stable Jetting Modes

Microparticle Formation via Tri-needle Coaxial Electrospray at Stable Jetting Modes

An Overview of Biopolymeric Electrospun Nanofibers Based on Polysaccharides for Wound Healing Management

Advances in Fabricating the Electrospun Biopolymer-Based Biomaterials

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