Characteristics of Elastomeric Nanofiber Membranes Produced by Electrospinning

Yamashita, Yuichi; Ko, Frank; Tanaka, Akira; Miyake, Hajime

doi:10.4188/jte.53.137

Cited by 34 publications

(16 citation statements)

References 13 publications

(10 reference statements)

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“…The significant enhancement of adhesion could be explained because the wet electrospun scaffold was produced using the low PES solution concentration (20 wt % and 18 wt %). The nanofiber diameter of 20 wt % PES and 18 wt % PES electrospun webs decreased to 329 nm and 215 nm, respectively, in agreement with the literature relating fiber diameter to polymer solution concentration 41–43. The low viscosity at low solution concentration can also be one of possible causes for the beading phenomenon of the electrospun scaffold at 20 wt % PES solution (Table 1, S5) and coalescence of electrospun web at 18 wt % PES solution (Table 1, S6).…”

Section: Resultssupporting

confidence: 86%

“…The diameter of electrospun nanofibers has been shown to increase with increasing polymer concentration 41–43. It is seen in Table 2 and Figure 2 that as the concentration decreased from 22 wt % to 20 wt %, the nanofibers became thinner but beads began to form within the scaffold.…”

Section: Resultsmentioning

confidence: 97%

“…7). The high polymer concentration and correspondingly high solution viscosity could be the possible causes resulting in an increase in the fiber diameter 42, 47. Because 0.5 wt % PEO additive led to an increase of adhesion of the nano‐PES/PET substrate but only affected slightly the nanofiber diameter, the 20 wt % PES solution with 0.5 wt % PEO additive was used for the electrospinning process to make a porous nano‐PES/PET composite support substrate for TFNC NF membrane, whose fabrication and performance evaluation will be described elsewhere.…”

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Design and fabrication of electrospun polyethersulfone nanofibrous scaffold for high‐flux nanofiltration membranes

Tang

Qiu

McCutcheon

et al. 2009

J Polym Sci B Polym Phys

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A novel class of high‐flux and low‐fouling thin‐film nanofibrous composite (TFNC) membranes, containing a thin hydrophilic top‐layer coating, a nanofibrous mid‐layer scaffold and a non‐woven microfibrous support, has been demonstrated for nanofiltration (NF) applications. In this study, the issues related to the design and fabrication of a polyethersulfone (PES) electrospun nanofibrous scaffold for TFNC NF membranes were investigated. These issues included the influence of solvent mixture ratio, solute concentration, additives, relative humidity (RH), and solution flow rate on the morphology of an electrospun PES nanofibrous scaffold, the distribution of fiber diameter, the adhesion between the PES scaffold and a typical poly(ethylene terephthalate) (PET) non‐woven support, as well as the tensile properties of the nanofibrous PES/non‐woven PET composite substrates. Uniform and thin nanofibrous PES scaffolds with strong adhesion to the nanofiber‐PET non‐woven are several of the key parameters to optimize the NF performance of TFNC membranes. © 2009 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 47: 2288–2300, 2009

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Section: Resultssupporting

confidence: 86%

Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Design and fabrication of electrospun polyethersulfone nanofibrous scaffold for high‐flux nanofiltration membranes

Tang

Qiu

McCutcheon

et al. 2009

J Polym Sci B Polym Phys

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“…The Berry's number is defined as the product of intrinsic viscosity and the polymer concentration of the solution. It was found that electrospinnability and fiber diameter can be correlated to the Berry number of the polymers 18. For example, the range of Berry's number for PAN polymer can be divided into four regions, with the first region corresponding to a Berry's number lower than 1, region 2 corresponding to a Berry's number between 1 and 2.7, and region 3 corresponding to 2.7–3.6, whereas region 4 corresponds to a Berry's number of above 3.6.…”

Section: Electrospun Structuresmentioning

confidence: 99%

Biomedical applications of nanofibers

Leung¹,

Ko²

2010

Polymers for Advanced Techs

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205

125

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Nanofiber technology is an exciting area attracting the attention of many researchers as a potential solution to the current challenges in the biomedical field such as burn and wound care, organ repair, and treatment for osteoporosis and various diseases. Nanofibers are attractive in this field for several reasons. First, surface area on nanofibers is much higher compared to bulk materials, which allows for enhanced adhesion of cells, proteins, and drugs. Second, nanofibers can be fabricated into sophisticated macro‐scale structures. The ability to fabricate nanofibers allows renewed efforts in developing hierarchical structures that mimic those in animals and human. On top of that, a wide range of polymers can be fabricated into nanofibers to suit different applications. Nanofibers are most commonly fabricated through electrospinning, which is a low cost method that allows control over fiber morphology and is capable of being scaled‐up for mass production. This review explored two popular areas of biomedical nanofiber development: tissue regeneration and drug delivery, and included discussions on the basic principles for how nanofibers promote tissue regeneration and drug delivery, the parameters that affect nanofiber performance and the recent progress in these areas. The recent work on biomedical nanofibers showed that the large surface area on nanofibers could be translated into enhanced cell activities, drug encapsulation, and drug release rate control. Furthermore, by optimizing the electrospinning process via adjusting the material choices and fiber orientation, for example, further enhancement in cell differentiation and drug release control could be achieved. Copyright © 2010 John Wiley & Sons, Ltd.

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“…So far, several efforts have been made to increase the production rate of nanofibers. For instance, modified single-needle [17,18], multi-needle [19][20][21][22][23][24][25][26][27], needleless systems [28][29][30][31][32][33][34], a plastic filter set-up [35] and forcespinning have been developed to enhance nanofiber production rate. Forcespinning TM or centrifuge spinning uses centrifugal force, rather than electrostatic force, as in the electrospinning process [36].…”

Section: Introductionmentioning

confidence: 99%

Experimental and numerical study on isolated and non-isolated jet behavior through centrifuge spinning system

Valipouri

Ravandi

Pishevar

et al. 2015

International Journal of Multiphase Flow

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This work presents a comparison between an isolated and a non-isolated curved liquid jet emerging from a rotating nozzle through centrifuge spinning system. In the centrifugal spinning process, a polymer solution has been pushed by the centrifugal force through small nozzle of a rapidly rotating cylindrical drum. Thereby thin fibers are formed and collected on a collector in the form of a web. Centrifuge spinning suffered from a strong air resistance which leads to a more deflected jet as well as its rapidly solvent evaporation resulting in thicker nanofibers. In this work, centrifuge spinning has been equipped by a rotating collector, whereas the fabrication process was skillfully sealed from ambient airflow. A comparison was drawn between the trajectory of Newtonian liquid jets fabricated by centrifuge spinning and air-sealed centrifuge spinning. The captured images of the liquid jet trajectory using a high speed camera showed that non-isolated liquid jets were more curved than isolated liquid jets due to air resistance. A pre-presented non-linear analysis of the Navier-Stokes equations was carried out and the numerical solutions were compared with the experiments.There was fairly good agreement between the isolated jet trajectory and the model-predicted one, but there were differences between the non-isolated jet trajectory and the simulation results. The non-isolated jet curved more compared to the others due to air drag. Also, the diameter of polymeric nanofibers was predicted and compared with experiments. Some qualitative agreement was found

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Characteristics of Elastomeric Nanofiber Membranes Produced by Electrospinning

Cited by 34 publications

References 13 publications

Design and fabrication of electrospun polyethersulfone nanofibrous scaffold for high‐flux nanofiltration membranes

Design and fabrication of electrospun polyethersulfone nanofibrous scaffold for high‐flux nanofiltration membranes

Biomedical applications of nanofibers

Experimental and numerical study on isolated and non-isolated jet behavior through centrifuge spinning system

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