A UV-cured nanofibrous membrane of vinylbenzylated gelatin-poly(ɛ-caprolactone) dimethacrylate co-network by scalable free surface electrospinning

Bazbouz, Mohamed Basel; He, Liang; Tronci, Giuseppe

doi:10.1016/j.msec.2018.05.076

Cited by 26 publications

(25 citation statements)

References 99 publications

(133 reference statements)

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“…It is well known that gelatin nanofibrous membrane tends to be rubber-like in the wet stage and rigid-brittle in the dry stage [65]. is was mainly attributed to the presence of the EMImBF 4 solution dispersed in the pores of nanofibrous membrane, thus weakening the interaction among neighboring fibers [66,67].…”

Section: Effect Of Emimbf 4 On Ges Ges-25 After Immersionmentioning

confidence: 99%

Preparation and Characterization of Electrospun Gelatin Nanofibers for Use as Nonaqueous Electrolyte in Electric Double-Layer Capacitor

Kotatha

Hirata

Ogino

et al. 2019

Journal of Nanotechnology

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A novel nanofibrous gel electrolyte was prepared via gelatin electrospinning for use as a nonaqueous electrolyte in electric double-layer capacitors (EDLCs). An electrospinning technique with a 25 wt% gelatin solution was applied to produce gelatin electrospun (GES) nanofiber electrolytes. Structural analysis of the GES products showed a clearly nanofibrous structure with fiber diameters in the 306.2–428.4 nm range and exhibiting high thermal stability, high tensile strength, and a stable form of nanofibrous structure after immersion in 1-ethyl-3-methylimidazolium tetrafluoroborate (EMImBF4). After testing over a range of spinning times, GES electrolytes that were produced at 25 min (GES-25) had a suitable thickness for the assembly of EDLC with the optimized tensile properties and were used to fabricate EDLC test cells with EMImBF4. These test cells were compared to those with pure EMImBF4 and a separator as an electrolyte. The electrochemical properties of the test cells were characterized by charge-discharge testing, discharge capacitance, and alternative current (AC) impedance measurements. AC impedance measurements showed that the test cell with the GES-25/EMImBF4 gel electrolyte showed slightly poorer contact with the electrode when compared to that with pure EMImBF4, whereas exhibited comparable IR drop and discharge capacitance (calculated capacitance retention was 56.6%). The results demonstrated that this novel gel electrolyte can be used as a nonaqueous electrolyte in order to improve the safety in EDLCs.

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Section: Effect Of Emimbf 4 On Ges Ges-25 After Immersionmentioning

confidence: 99%

Preparation and Characterization of Electrospun Gelatin Nanofibers for Use as Nonaqueous Electrolyte in Electric Double-Layer Capacitor

Kotatha

Hirata

Ogino

et al. 2019

Journal of Nanotechnology

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“…FSE was utilised to overcome the production scale limitations of needle-based electrospinning [ 30 ] and created a highly porous nonwoven membrane constructed of nanoscale diameter fibres. More than 95% of pores in PCL3%-E had a diameter of 1–2 μm, such that MSCs and fibroblasts are unlikely to penetrate due to size exclusion as BM MSCs have a diameter of 12–21 μm [ 35 , 36 , 37 ].…”

Section: Discussionmentioning

confidence: 99%

“…Our design strategy was to select a clinically approved biodegradable material, i.e., poly(ε-caprolactone) (PCL), given its extensive body of literature, prevalent use in existing medical devices, and an established safety and functionality understanding [ 25 , 26 , 27 , 28 ]. Then, to overcome the well-known production limitations of needle electrospinning [ 29 , 30 ] and enable scalable manufacturing consistent with industrial needs, free surface electrospinning (FSE) was employed to a membrane suitable for application in CSBDs. Together with the physical characterisation, functional testing of the membrane was carried out in vitro to assess the absorption and release of PL, MSCs interactions, as well as the barrier functionality to cell migration.…”

Section: Introductionmentioning

confidence: 99%

Induced Periosteum-Mimicking Membrane with Cell Barrier and Multipotential Stromal Cell (MSC) Homing Functionalities

Owston

Moisley

Tronci

et al. 2020

IJMS

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The current management of critical size bone defects (CSBDs) remains challenging and requires multiple surgeries. To reduce the number of surgeries, wrapping a biodegradable fibrous membrane around the defect to contain the graft and carry biological stimulants for repair is highly desirable. Poly(ε-caprolactone) (PCL) can be utilised to realise nonwoven fibrous barrier-like structures through free surface electrospinning (FSE). Human periosteum and induced membrane (IM) samples informed the development of an FSE membrane to support platelet lysate (PL) absorption, multipotential stromal cells (MSC) growth, and the prevention of cell migration. Although thinner than IM, periosteum presented a more mature vascular system with a significantly larger blood vessel diameter. The electrospun membrane (PCL3%-E) exhibited randomly configured nanoscale fibres that were successfully customised to introduce pores of increased diameter, without compromising tensile properties. Additional to the PL absorption and release capabilities needed for MSC attraction and growth, PCL3%-E also provided a favourable surface for the proliferation and alignment of periosteum- and bone marrow derived-MSCs, whilst possessing a barrier function to cell migration. These results demonstrate the development of a promising biodegradable barrier membrane enabling PL release and MSC colonisation, two key functionalities needed for the in situ formation of a transitional periosteum-like structure, enabling movement towards single-surgery CSBD reconstruction.

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“…Gelatin nanofibers (like collagen) have been used in biomedical applications such as cosmetics, wound dressing, tissue engineering, surgical treatments, etc [34]. Gelatin nanofibers (having sufficient mechanical properties to be used in these applications as nanofibrous mats) have been electrospun for ultrathin nanofibers [34][35][36][37][38][39][40][41][42][43][44]. These authors also reported that the properties of these nanofibers can be tailored as per requirements by optimizing input parameters such as voltage, viscosity, distance between the spinneret and rotating drum collector, and flow rate.…”

Section: Introductionmentioning

confidence: 99%

Electrospinning process parameters optimization for biofunctional curcumin/gelatin nanofibers

Kanu

Gupta

Vates

et al. 2020

Mater. Res. Express

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Electrospinning has received wide attention for the preparation of uniform diameter nanofibers (ranging from 5 nm to several hundred nanometers) in films with random as well as aligned fashions of the fibers of various materials for use in biomedical applications. Electrospinning research has provided an in-depth understanding of the preparation of light weight, ultrathin, porous, biofunctional curcumin/gelatin nanofibers having applications in wound dressing, drug release, tissue engineering, etc. In the first half of this article, prior research on electrospun curcumin/gelatin nanofibers is reviewed in depth with nanofibers being desired due to their low diameters since these would have then large surface area to volume ratio and enough film porosity as well as improved mechanical (tensile) strength so that when prepared as mats these nanofibers (having high biocompatibility) could be used for sustained release of curcumin and oxygen to wounds during healing. The synthesis of ultrathin nanofibers (having minimum average diameter) is not a simple task unless numerical investigation is carefully done in the first half of this research article. The authors research described here examined the effects of critical process parameters (in the second half of the paper) such as distance between the spinneret and collector, flow rate, voltage and solution viscosity, on the preparation of uniform and ultrathin nanofibers using scanning electron microscopy (SEM) for characterization of the nanofibers. A 2 k factorial design of experiment was found to be a suitable and efficient technique to optimize the critical process parameters used in the preparation of the biofunctional nanofibers with the purpose of having applications in the treatment of problematic wounds such as diabetic chronic ulcers. After parametric investigation, the distance, flow rate and voltage when taken together, were found to have the most significant contributions to the preparation of minimum diameter nanofibers. The primary objective of this research was fulfilled with the development of ultrathin curcumin/gelatin nanofibers having a 181 nm (181±66 nm) average diameter using the optimized setting of a solution having 1.5% gelatin, and 1% curcumin in 10 ml of 98% concentrated formic acid, with the electrospining unit having a voltage of 10 KV, distance from the spinneret to collector drum of 15 cm, flow rate of 0.1 ml h −1 , viscosity of 65 cP and drum collector speed of 1000 rpm. However, the lowest average diameter of nanofiber was measured around 147 nm (147±34 nm) which was prepared at a higher voltage, such as 15 KV (at 10 cm distance, 0.15 ml h −1 flow rate and 65 cP viscosity) using the solution. The design of this research paper is based on the view that merely optimization of biofunctional nanofibers may not fully satisfy researchers/ engineers unless they are also provided with sufficient information about (a) the entire electrospinning mechanism (numerical investigations of the mechanism) to have better control over preparation of ultr...

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A UV-cured nanofibrous membrane of vinylbenzylated gelatin-poly(ɛ-caprolactone) dimethacrylate co-network by scalable free surface electrospinning

Cited by 26 publications

References 99 publications

Preparation and Characterization of Electrospun Gelatin Nanofibers for Use as Nonaqueous Electrolyte in Electric Double-Layer Capacitor

Preparation and Characterization of Electrospun Gelatin Nanofibers for Use as Nonaqueous Electrolyte in Electric Double-Layer Capacitor

Induced Periosteum-Mimicking Membrane with Cell Barrier and Multipotential Stromal Cell (MSC) Homing Functionalities

Electrospinning process parameters optimization for biofunctional curcumin/gelatin nanofibers

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